Multimodal Biomarkers That Predict the Presence of Gleason Pattern 4: Potential Impact for Active Surveillance.

PURPOSE: Latent grade group ≥2 prostate cancer can impact the performance of active surveillance protocols. To date, molecular biomarkers for active surveillance have relied solely on RNA or protein. We trained and independently validated multimodal (mRNA abundance, DNA methylation, and/or DNA copy number) biomarkers that more accurately separate grade group 1 from grade group ≥2 cancers. MATERIALS AND METHODS: Low- and intermediate-risk prostate cancer patients were assigned to training (n=333) and validation (n=202) cohorts. We profiled the abundance of 342 mRNAs, 100 DNA copy number alteration loci, and 14 hypermethylation sites at 2 locations per tumor. Using the training cohort with cross-validation, we evaluated methods for training classifiers of pathological grade group ≥2 in centrally reviewed radical prostatectomies. We trained 2 distinct classifiers, PRONTO-e and PRONTO-m, and validated them in an independent radical prostatectomy cohort. RESULTS: PRONTO-e comprises 353 mRNA and copy number alteration features. PRONTO-m includes 94 clinical, mRNAs, copy number alterations, and methylation features at 14 and 12 loci, respectively. In independent validation, PRONTO-e and PRONTO-m predicted grade group ≥2 with respective true-positive rates of 0.81 and 0.76, and false-positive rates of 0.43 and 0.26. Both classifiers were resistant to sampling error and identified more upgrading cases than a well-validated presurgical risk calculator, CAPRA (Cancer of the Prostate Risk Assessment; P < .001). CONCLUSIONS: Two grade group classifiers with superior accuracy were developed by incorporating RNA and DNA features and validated in an independent cohort. Upon further validation in biopsy samples, classifiers with these performance characteristics could refine selection of men for active surveillance, extending their treatment-free survival and intervals between surveillance.

Genomic signatures of chromosomal instability and osteosarcoma progression detected by high resolution array CGH and interphase FISH.

Osteosarcoma (OS) is characterized by an unstable karyotype which typically has a heterogeneous pattern of complex chromosomal abnormalities. High-resolution array comparative genomic hybridization (CGH) in combination with interphase fluorescence in situ hybridization (FISH) analyses provides a complete description of genomic imbalances together with an evaluation of the contribution of cell-to-cell variation to copy number changes. There have been no analyses to date documenting genomic signatures consistent with chromosomal instability mechanisms in OS tumors using array CGH. In this study, we utilized high-resolution array CGH to identify and characterize recurrent signatures of genomic imbalances using ten OS tumors. Comparison between the genomic profiles identified tumor groups with low, intermediate and high levels of genomic imbalance. Bands 6p22-->p21, 8q24 and 17p12--> p11.2 were consistently involved in high copy gain or amplification events. Since these three locations have been consistently associated with OS oncogenesis, FISH probes from each cytoband were used to derive an index of cellular heterogeneity for copy number within each region. OS with the highest degree of genomic imbalance also exhibited the most extreme cell-to-cell copy number variation. Significantly, the three OS with the most imbalance and genomic copy number heterogeneity also had the poorest response to preoperative chemotherapy. This genome wide analysis is the first utilizing oligonucleotide array CGH in combination with FISH analysis to derive genomic signatures of chromosomal instability in OS tumors by studying genomic imbalance and intercellular heterogeneity. This comprehensive genomic screening approach provides important insights concerning the mechanisms responsible for generating complex genomes. The resulting phenotypic diversity can generate tumors with a propensity for an aggressive disease course. A better understanding of the underlying mechanisms leading to OS tumor development could result in the identification of prognostic markers and therapeutic targets.

Chromosomal instability in osteosarcoma and its association with centrosome abnormalities.

The mechanism that generates the extreme aneuploidy that characterizes osteosarcoma (OS) is poorly understood. In this study, interphase fluorescence in situ hybridization (FISH) analysis was used to enumerate cell-to-cell variation of several different chromosomes. We also investigated whether there was an association between TP53 mutation and centrosome aberrations in the generation of chromosomal aneuploidy in OS in four OS cell lines (HOS, SAOS2, U2OS, and MG63) and in a subset of seven tumors. Our analysis showed that there was a wide range of numerical changes affecting multiple chromosomes in OS cell lines and tumors. These data suggest that chromosomal instability (CIN) could be responsible for the extensive aneuploidy associated with this tumor. The results also showed an increased frequency of atypical mitotic figures in three OS cell lines with defective TP53, function and significantly, a more marked CIN phenotype was present in these lines. Furthermore, numerical aberrations of centrosomes were also present in these three OS cell lines with TP53 mutations. In two of three OS patients' tumors there was a large increase in the percentage of abnormal centrosome numbers. We conclude that CIN is a consistent feature of OS and that an intrinsic disturbance of the chromosomal segregation mechanisms is likely associated with centrosome aberrations.

Evidence of chromosomal instability in prostate cancer determined by spectral karyotyping (SKY) and interphase fish analysis.

The way in which cytogenetic aberrations develop in prostate cancer (CaP) is poorly understood. Spectral karyotype (SKY) analysis of CaP cell lines has shown that they have unstable karyotypes and also have features associated with chromosomal instability (CIN). To accurately determine the incidence of de novo structural and numerical aberrations in vitro in CaP, we performed SKY analysis of three independent clones derived from one representative cell line, DU145. The frequent generation of new chromosomal rearrangements and a wide variation in the number of structural aberrations within two to five passages suggested that this cell line exhibited some of the features associated with a CIN phenotype. To study numerical cell-to-cell variation, chromosome 8 aneusomy was assessed in the LNCaP, DU145, and PC-3 cell lines and a patient cohort of 15 CaP primary tumors by interphase fluorescence in situ hybridization (FISH). This analysis showed that a high frequency of numerical alteration affecting chromosome 8 was present in both in vitro and in CaP tissues. In comparison to normal controls, the patient cohort had a statistically significant (P<.05), greater frequency of cells with one and three centromere 8 copies. These data suggest that a CIN-like process may be contributing towards the generation of de novo numerical and structural chromosome abnormalities in CaP.

Identification of a high frequency of chromosomal rearrangements in the centromeric regions of prostate cancer cell lines by sequential giemsa banding and spectral karyotyping.

BACKGROUND: Currently, prostate cancer (CaP) cytogenetics is not well defined, largely because of technical difficulties in obtaining primary tumor metaphases. METHODS AND RESULTS: We examined three CaP cell lines (LNCaP, DU145, PC-3) using sequential Giemsa banding and spectral karyotyping (SKY) to search for a common structural aberration or translocation breakpoint. No consistent rearrangement common to all three cell lines was detected. A clustering of centromeric translocation breakpoints was detected in chromosomes 4, 5, 6, 8, 11, 12, 14, and 15 in DU145 and PC-3. Both these lines were found to have karyotypes with a greater level of complexity than LNCaP. CONCLUSION: The large number of structural aberrations present in DU145 and PC-3 implicate an underlying chromosomal instability and subsequent accumulation of cytogenetic alterations that confer a selective growth advantage. The high frequency of centromeric rearrangements in these lines indicates a potential role for mitotic irregularities associated with the centromere in CaP tumorigenesis.

Association of DNAse sensitive chromatin domains with the nuclear periphery in 3T3 cells in vitro.

DNAse sensitive chromatin, putative transcriptionally competent sequences, exists either as pan-nuclear speckles in cells with nuclei which exhibit a flat geometry, or as a shell apposed to the nuclear envelope in cells with spheroidal nuclei. To test the hypothesis that DNAse sensitive chromatin is similarly associated with the nuclear periphery in cell types with a very flat geometry such as 3T3 fibroblasts, cells were subjected to hypotonic expansion to change their nuclei from a flat ellipsoid to a spheriod. This was based on the assumption that such a spatial association is not resolvable due to the interdigitation at the nuclear midplane of DNAse sensitive chromatin associated with the upper and lower nuclear surfaces. In situ nick translation was used to visualize the distribution of DNAse sensitive chromatin as a function of nuclear geometry. Both unexpanded and expanded cells exhibit DNAse sensitive chromatin as a dome at the apical side of the nucleus, i.e., that aspect of the cell facing the culture medium. The results argue for a polarized association of DNAse sensitive chromatin with the nuclear envelope and indicate that the nuclear periphery may function as a compartment for the spatial coupling of transcription and nucleo-cytoplasmic transport.

Dynamics of structure-function relationships in interphase nuclei.

The interphase nucleus is a topologically ordered, three-dimensional structure. While it remains unclear whether this structural organization also represents compartmentalization of function, the presence of the latter would likely be reflected in the spatial coupling of molecular factors involved in related events. This review summarizes morphological evidence, derived from in situ experiments, which indicates the existence of compartmentalization of both chromatin and non-chromatin components in the interphase nucleus. Moreover, the review addresses the spatial relationships of these components relative to each other and correlates these spatial relationships with such nuclear functions as transcription, splicing and nucleo-cytoplasmic transport of pre-mRNA. Given that it is increasingly recognized that such spatial relationships are dynamic, the review also addresses the emerging concept that the spatial intranuclear organization changes with changes in cell function, a concept which supports the hypothesis that the spatial organization of the interphase nucleus may represent one of the fundamental control mechanisms in gene expression.

A specific conformation of the territory of chromosome 17 locates ERBB-2 sequences to a DNase-hypersensitive domain at the nuclear periphery.

Chromatin in interphase nuclei exhibits a topology that is associated with the transcriptional state of cells. We examined the spatial, intranuclear distribution of chromosome 17 and the ERBB-2 (HER2/neu) sequence thereon, relative to that of DNase-hypersensitive chromatin (DHC), in breast tumour cells exhibiting different levels of expression of ERBB-2. These sequences were specifically associated with the nuclear periphery, within a band of DHC. The remainder of the chromosome 17 mass showed no preferential position within the nucleus. The peripheral placement of ERBB-2 sequences is associated with a specific conformation of chromosome 17. We propose that the conformational organization of chromosome territories might represent a fundamental control mechanism in gene expression.

Changes in morphology and spatial position of coiled bodies during NGF-induced neuronal differentiation of PC12 cells.

Interphase nuclei are organized into structural and functional domains. The coiled body, a nuclear organelle of unknown function, exhibits cell type-specific changes in number and morphology. Its association with nucleoli and with small nuclear ribonucleo-proteins (snRNPs) indicates that it functions in RNA processing. In cycling cells, coiled bodies are round structures not associated with nucleoli. In contrast, in neurons, they frequently present as nucleolar "caps." To test the hypothesis that neuronal differentiation is accompanied by changes in the spatial association of coiled bodies with nucleoli and in their morphology, PC12 cells were differentiated into a neuronal phenotype with nerve growth factor (NGF) and coiled bodies detected by immunocytochemical localization of p80-coilin and snRNPs. The fraction of cells that showed coiled bodies as nucleolar caps increased from 1.6 +/- 0.9% (mean +/- SEM) in controls to 16.5 +/- 1.6% in NGF-differentiated cultures. The fraction of cells with ring-like coiled bodies increased from 17.2 +/- 5.0% in controls to 57.8 +/- 4.4% in differentiated cells. This was accompanied by a decrease, from 81.2 +/- 5.7% to 25.7 +/- 3.1%, in the fraction of cells with small, round coiled bodies. SnRNPs remained associated with typical coiled bodies and with ring-like coiled bodies during NGF-induced recruitment of snRNPs to the nuclear periphery. Together with the observation that coiled bodies are also present as nucleolar caps in sensory neurons, the results indicate that coiled bodies alter their morphology and increase their association with nucleoli during NGF-induced neuronal differentiation.

Transposition of DNase hypersensitive chromatin to the nuclear periphery coincides temporally with nerve growth factor-induced up-regulation of gene expression in PC12 cells.

To test the hypothesis that the nonrandom organization of the contents of interphase nuclei represents a compartmentalization of function, we examined the relative, spatial relationship of small nuclear ribonucleoproteins (snRNPs) and of DNase I hypersensitive chromatin (DHC) in rat pheochromocytoma cells. In controls, DHC and snRNPs colocalized as pan-nuclear speckles. During nerve growth factor-induced differentiation, both snRNPs and DHC migrated to the nuclear periphery with the migration of DHC preceding that of snRNPs, resulting in their transient separation. The formation of DHC shells temporally coincided with an up-regulation of neurofilament light chain mRNA. This indicates that the expression of this sequence may be associated with its spatial transposition to the nuclear periphery.

Organization of centromeric domains in hepatocyte nuclei: rearrangement associated with de novo activation of the vitellogenin gene family in Xenopus laevis.

The existence of a function-dependent, nonrandom organization of chromatin domains within interphase nuclei is supported by evidence which suggests that specific chromatin domains undergo spatial rearrangement under conditions which alter gene expression. Exposure to estrogen of male Xenopus laevis hepatocytes in vitro results in de novo activation of vitellogenin mRNA production and vitellogenin protein synthesis and provides an ideal model to study the association between chromatin organization and changes in gene expression. In a test of the hypothesis that the de novo induction of vitellogenesis in male X. laevis is associated with a spatial rearrangement of specific chromatin domains, centromeric regions were localized by immunofluorescent labeling of associated kinetochore proteins in naive and in estrogen-treated, vitellogenic cells. Analyses by confocal scanning laser microscopy of the three-dimensional spatial distribution of kinetochores in estrogen-treated male hepatocytes showed that a significantly greater proportion of signals was associated with the nuclear periphery than in non-estrogen-treated, naive male cells. In hepatocyte nuclei, quantification of kinetochore signal sizes using image analysis showed that these signals were fewer in number and showed greater variation in size than those of cells in metaphase, with larger signals exhibiting total normalized fluorescence intensities of two, three, four, and five times that associated with kinetochore signals of metaphase cells. These observations are taken to reflect the existence of clustering of kinetochores and, by extension, of centromeres in these cells. In summary, the results show that centromeric domains within interphase nuclei of Xenopus hepatocytes occur as clusters and that these domains undergo spatial rearrangement under conditions which alter the transcriptional state of the cell.

Distribution of snRNPs, splicing factor SC-35 and actin in interphase nuclei: immunocytochemical evidence for differential distribution during changes in functional states.

Small nuclear ribonucleoproteins (snRNPs) play an integral role in the processing of pre-mRNA in eukaryotic nuclei. snRNPs often occur in a speckled intranuclear distribution, together with the non-snRNP splicing factor SC-35. snRNPs have also been shown to be associated with actin in the nuclear matrix, suggesting that both actin and snRNPs may be involved in the processing and transport of transcripts. The work reported here was undertaken to compare the spatial relationship of snRNPs, SC-35, and intranuclear actin in neuronal and non-neuronal cell types. In undifferentiated PC12 cells and in non-neuronal cells growing in association with dorsal root ganglion neurons, confocal immunocytochemistry revealed a typical, speckled distribution of snRNP aggregates, which colocalized with the SC-35 splicing factor. In contrast, a unique snRNP distribution was observed in dorsal root ganglion neurons in vitro and in PC12 cells differentiated by nerve growth factor. In nuclei of these cells, snRNPs were predominantly located at the periphery where they formed a spherical shell apposed to the nuclear envelope. Ultrastructural immunogold labelling of snRNPs in dorsal root ganglion neurons in vitro confirmed this distribution. In contrast, SC-35 remained distributed in a speckled pattern throughout nuclei of dorsal root ganglion neurons and PC12 cells, even in cases where snRNPs were almost exclusively positioned at the nuclear periphery. In non-neuronal cells in dorsal root ganglion cultures and in undifferentiated PC12 cells, snRNP aggregates were frequently associated with actin aggregates, as determined by Nearest Neighbor Analyses. In PC12 cells, this spatial relationship was altered during nerve growth factor-induced differentiation, prior to the time at which these cells showed morphological evidence of differentiation. Specifically, Nearest Neighbor Analyses between snRNP and actin aggregates in PC12 cells exposed to nerve growth factor for 4 hours revealed that snRNP and actin aggregates exhibited a closer association than in undifferentiated cells. These results suggest that sites of pre-mRNA processing and transcription may differ between cell types, and that the functions of snRNPs and actin within interphase nuclei may be related. The results also indicate that the distribution of snRNPs is dynamic and that it may depend upon the functional state of the cell as well as upon its state of differentiation.

Spatial rearrangement and enhanced clustering of kinetochores in interphase nuclei of dorsal root ganglion neurons in vitro: association with nucleolar fusion.

Interphase nuclei of several cell types display distinct, nonrandom arrangements of specific chromatin domains. It has been suggested that this arrangement is associated with the functional commitment of the cell and results from compartmentalization of specific DNA sequences to transcriptionally competent sites. In a test of the hypothesis that such topological organization is established during cellular differentiation, the spatial distribution of centromeres was determined, in dorsal root ganglion neurons in vitro, using immunocytochemistry in conjunction with fluorescence microscopy, confocal laser microscopy, and ultrastructural immunogold techniques. Kinetochores occurred as clusters, in association with nucleoli and with the nuclear envelope. Neurons at different stages of differentiation, as determined by nucleolar distribution, exhibited a distinct, stage-specific, spatial organization of kinetochores. Morphometric analyses, together with serial reconstruction, indicated that progressive clustering of kinetochores accompanies differentiation and that such clustering occurs in association with nucleolar fusion. The data presented indicate that the chromatin organization observed in the fully differentiated state may be the result of controlled rearrangements of specific chromatin domains during differentiation and that the mechanism governing such rearrangement and the process of cellular differentiation may be linked.

Nuclear membrane modifications in polytene nuclei of Drosophila melanogaster: serial reconstruction and cytochemistry.

The nuclear envelope of polytene nuclei of salivary glands of Drosophila melanogaster displays modifications consisting of nuclear envelope invaginations (NEI) and evaginations (NEE). Ultrastructural analyses combined with three-dimensional reconstruction and cytochemistry show that NEI are bounded by a single membrane and that they may arise as invaginations of the inner nuclear membrane. NEI extend deeply into the nucleus. The lumens of NEI may collapse resulting in membranous sheets which may combine with those arising from adjacent NEI to form intranuclear structures resembling annulate lamellae. All NEI are associated with NEE. In contrast to NEI, NEE are enclosed in a double membrane morphologically identical to the nuclear envelope. While NEI and NEE share wheat germ agglutinin binding properties with the nuclear envelope, they differ in their ability to localize lanthanum. Pore annuli of NEI display complete lack of lanthanum binding, while those of NEE exhibit minor deposition of this cation. In contrast, pore annuli of the nuclear envelope are specifically and significantly decorated by lanthanum. A conceptual model based on the results obtained suggests that NEI are formed by invaginations of the inner nuclear membrane, together with accompanying modifications of pore complexes.

Dynamics of nucleolar fusion in neuronal interphase nuclei in vitro: association with nuclear rotation.

Nuclear rotation (NR) refers to the motion of chromatin domains in interphase nuclei of several cell types, including neurons, in vitro. It has been proposed that NR may function, during cellular differentiation, in the transposition of specific chromatin domains into the cytotypic chromosome pattern known to exist in interphase nuclei. It is controversial whether NR represents motion of nuclei in toto, including the nuclear envelope, or whether NR represents independent motion of subnuclear structures, relative to each other. Using nucleoli as markers of chromatin motion in dorsal root ganglion neurons in vitro, we now show that trajectories of individual nucleoli are spatially restricted to subnuclear domains. Nucleoli move at mean rates of 2.153 +/- 0.037 deg/min and exhibit periodic fluctuations in rate. Fast Fourier transform analyses show dominant frequencies ranging from 0.47 c/h to 2.91 c/h. The power spectra of periodic motion of 15 of 25 nucleoli monitored exhibit resonance which suggests that NR represents forced harmonic motion. Quantification of motion of nucleoli in differentiating, multinucleolate neurons showed that internucleolar distances may rapidly decrease, culminating in nucleolar fusion, and showed that nucleolar fusion was invariably associated with a transient increase in the rate of NR. These results indicate that nucleoli may move independently; that an association exists between rearrangement of chromatin domains and NR; and that NR, nucleolar fusion, and differentiation are linked.