Correlation between centrosome abnormalities and chromosomal instability in human pancreatic cancer cells

Numerical and structural centrosome aberrations are an early and stable event in the adenoma–carcinoma sequence of colorectal carcinomas

AIMS

Numerical and structural centrosome changes have been described for and linked with genetic instability in solid tumors. Here, we specifically address centrosome aberrations in the adenoma-carcinoma sequence of colorectal cancer by detailed evaluation of gamma-tubulin staining patterns.

METHODS

Formalin-fixed and paraffin-embedded specimens (normal colonic epithelium n=21; low-grade intraepithelial neoplasia n=27, high-grade intraepithelial neoplasia n=16 and invasive adenocarcinomas n=33) were stained by an anti-gamma-tubulin antibody using standard immunofluorescence. Three-dimensional image stacks of the stainings were recorded (Zeiss LSM510 confocal microscope), followed by numerical and structural data analysis (DIAS software package) and statistical evaluation (NCSS-software).

RESULTS

The mean centrosome signal per cell differed significantly (P<0.0001) between normal colonic epithelium (0.8775) and each low-grade intraepithelial neoplasia (1.787), high-grade intraepithelial neoplasia (2.259) and invasive carcinomas (2.267). Similarly, both the centrosomes' structural entropy (SE) and minimal spanning tree (MST) differed significantly (P<0.001) between normal (SE=3.956, MST=38.78) and each low- (SE=6.39, MST=26) and high-grade intraepithelial neoplasia (SE=5.75, MST=26.97) and invasive carcinoma (SE=6.86, MST=28.08).

CONCLUSION

Numerical and structural centrosome dysregulation is seen as early as in low-grade dysplastic lesions of the adenoma-carcinoma sequence of colorectal carcinomas and may, as such, play an initial role in the carcinogenic process.

Chromosomal instability in oral cancer cells

Chromosomal instability is a common feature of human tumors, including oral cancer. Although a tumor karyotype may remain quite stable over time, chromosomal instability can lead to 'variations on a theme' of a clonal cell population, often with each cell within a tumor possessing a different karyotype. Thus, chromosomal instability appears to be an important acquired feature of tumor cells, since propagation of such a diverse cell population may facilitate evasion of standard therapies. There are several sources of chromosomal instability, although the primary causes appear to be defects in chromosomal segregation, telomere stability, cell-cycle checkpoint regulation, and the repair of DNA damage. Our understanding of the biological basis of chromosomal instability in cancer cells is increasing rapidly, and we are finding that the seemingly unrelated origins of this phenomenon may actually be related through the complex network of cellular signaling pathways. Here, we review the general causes of chromosomal instability in human tumors. Specifically, we address the state of our knowledge regarding chromosomal instability in oral cancer, and discuss various mechanisms that enhance the ability of cancer cells within a tumor to express heterogeneous karyotypes. In addition, we discuss the clinical relevance of factors associated with chromosomal instability as they relate to tumor prognosis and therapy.

p53 deficiency exacerbates pleiotropic mitotic defects, changes in nuclearity and polyploidy in transdifferentiating pancreatic acinar cells

In a primary culture model for pancreatic acinar-ductal transdifferentiation, cells exhibited increased proliferation, changes in nuclearity and polyploidy. We identify the 'nucleus to centrosome' ratio of the progenitor cell, the dissemination of centrosomes at spindle poles and cytokinesis failure as critical determinants of mitosis outcome and centrosome inheritance. Abortive cytokinesis of mononuclear cells contributes to the binuclear cell pool, whereas enclosure of entire mitotic formations, within a single nuclear envelope, perpetuates polyploidization. Binuclear cell nuclei combine their genomes on a single metaphase plate, doubling descendant ploidy. Moreover, approximately 42% of binuclear and tetraploid cells assemble aberrant spindles with up to 8 centrosomes/poles. These phenotypes were exacerbated in p53-deficient cultures exhibiting increased S-phase entry, giant nuclei, multinucleation, multipolar mitoses and centrosome hyperamplification. The tendency of p53-proficient cells to spontaneously evade the tetraploidy checkpoint degenerates to uncontrolled polyploid progression in p53-deficient cultures, explaining why p53 abrogation alone rapidly descends to aneuploidy in this system. We detected constitutively nuclear mdm2, which may circumvent endogenous cell-cycle checkpoints, and pronounced accumulation of p21 and p27 in multinuclear cells and giant nuclei, consistent with roles in polyploidization. This in vitro model may recapitulate the processes underlying genomic instability in pancreatic tumours in vivo, and attests to the existence of a p53-dependent polyploidy checkpoint acting to limit the degree of polyploidization.

Connecting mitotic instability and chromosome aberrations in cancer—can telomeres bridge the gap?

Gross mitotic disturbances are often found in malignant tumours, but not until recently have the molecular causes and the genomic consequences of these abnormalities started to become known. One potential source of mitotic instability is chromosomes with dysfunctional telomeres, giving rise to a high rate of chromatin bridges at anaphase. These bridges could lead either to structural chromosome rearrangements through chromatin fragmentation or to whole-chromosome losses through kinetochore-spindle detachment. Statistical meta-analyses have recently revealed that tumours with high rates of anaphase bridging, such as ovarian, head and neck, and pancreatic carcinomas, are characterised by multimodal distributions of genomic imbalances, consistent with a dramatically increased rate of chromosome rearrangements. In contrast, tumours without gross cell division disturbances are characterised by a monotonously decreasing distribution of genomic changes. This distribution follows a power-law, best described by a preferential attachment model in which the tolerance for chromosomal changes increases steadily with tumour growth. Even though many common cancers, such as breast, colorectal, and renal cell carcinomas adhere to this simple power-law dynamics, the underlying molecular mechanisms remain elusive.

Spindle multipolarity is prevented by centrosomal clustering

Most tumor cells are characterized by increased genomic instability and chromosome segregational defects, often associated with hyperamplification of the centrosome and the formation of multipolar spindles. However, extra centrosomes do not always lead to multipolarity. Here, we describe a process of centrosomal clustering that prevented the formation of multipolar spindles in noncancer cells. Noncancer cells needed to overcome this clustering mechanism to allow multipolar spindles to form at a high frequency. The microtubule motor cytoplasmic dynein was a critical part of this coalescing machinery, and in some tumor cells overexpression of the spindle protein NuMA interfered with dynein localization, promoting multipolarity.

The Centrosome in Normal and Transformed Cells

The centrosome is a unique organelle that functions as the microtubule organizing center in most animal cells. During cell division, the centrosomes form the poles of the bipolar mitotic spindle. In addition, the centrosomes are also needed for cytokinesis. Each mammalian somatic cell typically contains one centrosome, which is duplicated in coordination with DNA replication. Just like the chromosomes, the centrosome is precisely reproduced once and only once during each cell cycle. However, it remains a mystery how this protein-based structure undergoes accurate duplication in a semiconservative manner. Intriguingly, amplification of the centrosome has been found in numerous forms of cancers. Cells with multiple centrosomes tend to form multipolar spindles, which result in abnormal chromosome segregation during mitosis. It has therefore been postulated that centrosome aberration may compromise the fidelity of cell division and cause chromosome instability. Here we review the current understanding of how the centrosome is assembled and duplicated. We also discuss the possible mechanisms by which centrosome abnormality contributes to the development of malignant phenotype.

The occurrence of chromosome segregational defects is an intrinsic and heritable property of oral squamous cell carcinoma cell lines

Chromosomal segregational defects are commonly observed in cancer cells and are an important source of genetic instability. It is currently unknown whether these mitotic defects are the result of a subpopulation of defective cells or reflect characteristics of the population of cells as a whole. In this study, we compared chromosomal segregational defects in two oral squamous cell carcinoma cell lines and five single-cell clones from each of those cell lines. We used immunofluorescence microscopy to quantitate the occurrence of multipolar metaphase spindles, lagging chromosomes at metaphase and anaphase, and anaphase bridges. We conclude that chromosome segregational defects in these cancer cell lines represent an intrinsic and inherited tendency toward segregational defects in the general cell population, rather than the existence of a subpopulation of cells with segregational defects.

Distinct MDM2 and P14ARF expression and centrosome amplification in well-differentiated liposarcomas

Well-differentiated liposarcomas (WDLs) are common soft-tissue tumors in adults. They are characterized by large marker chromosomes and/or ring chromosomes containing 12q-derived sequences in which MDM2 is consistently amplified. WDLs are subdivided into two subtypes according to their karyotype. Type D cells exhibit a near-diploid karyotype, with very few or no chromosome changes. Type H cells exhibit a near-tetraploid karyotype and many structural changes. Expression of P14ARF, MDM2, and TP53 proteins was assayed in the two WDL subtypes to establish whether distinct expression profiles correlated with cell ploidy. Although a transcriptionally functional TP53 was present in most tumors independent of their karyotype, type H cells were characterized by high levels of P14ARF and MDM2 proteins. Although amplified within similar chromosome markers in type D tumors, MDM2 did not appear to be overexpressed. In addition, it was present as a C-terminal truncated protein, indicative of alternatively spliced variants of MDM2 mRNA. As the existence of karyotypically distinct tumors could result from alterations of the mitotic machinery, we investigated the centrosome behavior in the two WDL subtypes. Centrosome amplification occurred in WDL tumors types H and D independent of their ploidy status. Moreover, no functional centrosome difference was found between the two tumor subtypes.

Centrosomal abnormality is common in and a potential biomarker for bladder cancer

Centrosomal abnormalities have been implicated in chromosomal segregation aberrations that result from the formation of multipolar mitotic spindles and lead to aneuploidy. Aneuploidy is a characteristic of neoplasia and underlies the development and progression of bladder cancer. Therefore, centrosomal abnormality may play a key role in urothelial tumor transformation. The purpose of our investigation was to determine whether centrosomal abnormalities are present in malignant urothelial cells, define the relationship between centrosomal abnormalities and aneuploidy and determine whether the presence of centrosomal abnormalities might be a potential diagnostic marker for bladder cancer. Bladder wash specimens obtained from patients with and without a history of urothelial carcinoma were analyzed for centrosomal abnormalities using an immunoassay with a gamma-tubulin antibody. FISH with centromeric probes for chromosomes 4 and 9 and DNA ploidy image analysis were performed to detect aneuploidy. Defective centrosomes were found in 40 of 45 bladder wash specimens from patients with bladder cancer but in none of the 10 samples from patients without it. A large percentage (69%) of grade 1 tumors were positive for centrosomal abnormalities, and these abnormalities were increasing in numbers and size in grade 2 (93%) and grade 3 (100%) specimens. Centrosomal abnormalities and numerical chromosomal aberrations frequently appeared concomitantly in the same malignant cells. All of the specimens showing aneuploidy also exhibited centrosomal abnormalities: centrosomal defects and aneuploidy occurred together in 80% of malignant bladder tumors, with an especially high percentage in higher-grade tumors. The overall positivity of centrosomal abnormalities was higher than that of aneuploidy (88% vs. 80%), especially in grade 1 tumors (69% vs. 46%), whereas aneuploidy was strongly associated with grade 2 and grade 3 tumors. Centrosomal abnormalities are common in bladder cancer, even in low-grade tumors, and strongly associated with cancer grade and aneuploidy, especially in high-grade neoplasms. Centrosomal abnormalities appear to be intrinsic to aneuploidy and tumorigenesis and may be potential markers for early detection of bladder cancer.

Caught up in a Wnt storm: Wnt signaling in cancer

The Wnt signaling pathway, named for its most upstream ligands, the Wnts, is involved in various differentiation events during embryonic development and leads to tumor formation when aberrantly activated. Molecular studies have pinpointed activating mutations of the Wnt signaling pathway as the cause of approximately 90% of colorectal cancer (CRC), and somewhat less frequently in cancers at other sites, such as hepatocellular carcinoma (HCC). Ironically, Wnts themselves are only rarely involved in the activation of the pathway during carcinogenesis. Mutations mimicking Wnt stimulation-generally inactivating APC mutations or activating beta-catenin mutations-result in nuclear accumulation of beta-catenin which subsequently complexes with T-cell factor/lymphoid enhancing factor (TCF/LEF) transcription factors to activate gene transcription. Recent data identifying target genes has revealed a genetic program regulated by beta-catenin/TCF controlling the transcription of a suite of genes promoting cellular proliferation and repressing differentiation during embryogenesis, carcinogenesis, and in the post-embryonic regulation of cell positioning in the intestinal crypts. This review considers the spectra of tumors arising from active Wnt signaling and attempts to place perspective on recent data that begin to elucidate the mechanisms prompting uncontrolled cell growth following induction of Wnt signaling.

Pancreatic cancer biology and genetics

Pancreatic ductal adenocarcinoma is an aggressive and devastating disease, which is characterized by invasiveness, rapid progression and profound resistance to treatment. Advances in pathological classification and cancer genetics have improved our descriptive understanding of this disease; however, important aspects of pancreatic cancer biology remain poorly understood. What is the pathogenic role of specific gene mutations? What is the cell of origin? And how does the stroma contribute to tumorigenesis? A better understanding of pancreatic cancer biology should lead the way to more effective treatments.

Altered splicing pattern of TACC1 mRNA in gastric cancer

Transforming acidic coiled-coil (TACC) proteins are centrosome and microtubule-associated proteins that are essential for mitotic spindle function. We identified TACC1 as an immunogenic protein and a potential tumor antigen by applying serological identification of antigens by recombinant expression cloning (SEREX) technique to screen a gastric cancer cDNA library. The 5'RLM-RACE and reverse transcriptase polymerase chain reaction analyses revealed at least six different transcript variants of TACC1 with variable transcription start sites and alternative exon usage (designated TACC1-A-TACC1-F). All transcripts differ in their 5' ends but share an identical 3' region encoding coiled-coil domain. Four transcripts were universally expressed in all normal tissues analyzed but TACC1-D and TACC1-F showed a restricted expression pattern. TACC1-F, a transcript representing the SEREX-identified cDNA clone, was predominantly expressed in brain and gastric tumors to a similar level. TACC1-D was only weakly detectable in kidney and colon but not in other normal tissues, while a relatively strong expression was observed in 50% of gastric cancer tissue samples analyzed. These transcript variants are generated possibly as a result of alterations in efficiency and pattern of alternative splicing; these isoforms may represent genetic markers, for example TACC1-D for gastric cancer. We also propose that inappropriate expression of the isoforms in gastric cancer cells might result in dysfunction of TACC1 thus contributing to the genetic instability.

Centrosomal TACCtics

Although the centrosome was first described over 100 years ago, we still know relatively little of the molecular mechanisms responsible for its functions. Recently, members of a novel family of centrosomal proteins have been identified in a wide variety of organisms. The transforming acidic coiled-coil-containing (TACC) proteins all appear to play important roles in cell division and cellular organisation in both embryonic and somatic systems. These closely related molecules have been implicated in microtubule stabilisation, acentrosomal spindle assembly, translational regulation, haematopoietic development and cancer progression. In this review, I summarise what we already know of this protein family and will use the TACC proteins to illustrate the many facets that centrosomes have developed during the course of evolution.

Amplified centrosomes in breast cancer: a potential indicator of tumor aggressiveness

Molecular mechanisms leading to genomic instability and phenotypic variation during tumor development and progression are poorly understood. Such instability represents a major problem in the management of breast cancer because of its contribution to more aggressive phenotypes as well as chemoresistance. In this study we analyzed breast carcinomas and tumor-derived cell lines to determine the relationship between centrosome amplification and established prognostic factors. Our results show that centrosome amplification can arise independent of ER or p53 status and is a common feature of aneuploid breast tumors. Centrosome amplification is associated with mitotic spindle abnormalities in breast carcinomas and thus may contribute to genomic instability and the development of more aggressive phenotypes during tumor progression.

Protein kinase A and chromosomal stability

All malignant human tumors contain chromosomal rearrangements. Among them, the majority of solid tumors show chromosomal instability, caused by aberrations in chromosomal segregation during cell division. Chromosomal instability, defined as increased probability of formation of novel chromosomal mutations compared to that of normal or control cells, appears to be a feature of tumorigenesis in vivo and in vitro (in cancer cell lines). Several enzymatic kinases are involved in maintaining proper chromosomal segregation and regulating cell cycle progression. One such kinase, cAMP-dependent protein kinase A (PKA), has a functional role in many aspects of cell signaling, metabolism, and proliferation. In this review, we will discuss the potential participation of PKA in chromosomal stability. This role includes the association of PKA with the centrosome, microtubules, and the anaphase-promoting complex/cyclosome (ACP/C), all key aspects of proper chromosomal segregation.

Centrosome amplification drives chromosomal instability in breast tumor development

Earlier studies of invasive breast tumors have shown that 60-80% are aneuploid and approximately 80% exhibit amplified centrosomes. In this study, we investigated the relationship of centrosome amplification with aneuploidy, chromosomal instability, p53 mutation, and loss of differentiation in human breast tumors. Twenty invasive breast tumors and seven normal breast tissues were analyzed by fluorescence in situ hybridization with centromeric probes to chromosomes 3, 7, and 17. We analyzed these tumors for both aneuploidy and unstable karyotypes as determined by chromosomal instability. The results were then tested for correlation with three measures of centrosome amplification: centrosome size, centrosome number, and centrosome microtubule nucleation capacity. Centrosome size and centrosome number both showed a positive, significant, linear correlation with aneuploidy and chromosomal instability. Microtubule nucleation capacity showed no such correlation, but did correlate significantly with loss of tissue differentiation. Centrosome amplification was detected in in situ ductal carcinomas, suggesting that centrosome amplification is an early event in these lesions. Centrosome amplification and chromosomal instability occurred independently of p53 mutation, whereas p53 mutation was associated with a significant increase in centrosome microtubule nucleation capacity. Together, these results demonstrate that independent aspects of centrosome amplification correlate with chromosomal instability and loss of tissue differentiation and may be involved in tumor development and progression. These results further suggest that aspects of centrosome amplification may have clinical diagnostic and/or prognostic value and that the centrosome may be a potential target for cancer therapy.

Chromosome segregation and cancer: cutting through the mystery

Mitosis is the most dramatic--and potentially dangerous--event in the cell cycle, as sister chromatids are irreversibly segregated to daughter cells. Defects in the checkpoints that normally maintain the fidelity of this process can lead to chromosomal instability (CIN) and cancer. However, CIN--a driving force of tumorigenesis--could be the cancer cell's ultimate vulnerability. An important goal is to identify novel anticancer compounds that directly target the mitotic errors at the heart of CIN.