Characterizing the Genomic Profile in High-Grade Gliomas: From Tumor Core to Peritumoral Brain Zone, Passing through Glioma-Derived Tumorspheres

Glioblastoma is an extremely heterogeneous disease. Treatment failure and tumor recurrence primarily reflect the presence in the tumor core (TC) of the glioma stem cells (GSCs), and secondly the contribution, still to be defined, of the peritumoral brain zone (PBZ). Using the array-CGH platform, we deepened the genomic knowledge about the different components of GBM and we identified new specific biomarkers useful for new therapies. We firstly investigated the genomic profile of 20 TCs of GBM; then, for 14 cases and 7 cases, respectively, we compared these genomic profiles with those of the related GSC cultures and PBZ biopsies. The analysis on 20 TCs confirmed the intertumoral heterogeneity and a high percentage of copy number alterations (CNAs) in GBM canonical pathways. Comparing the genomic profiles of 14 TC-GSC pairs, we evidenced a robust similarity among the two samples of each patient. The shared imbalanced genes are related to the development and progression of cancer and in metabolic pathways, as shown by bioinformatic analysis using DAVID. Finally, the comparison between 7 TC-PBZ pairs leads to identifying PBZ-unique alterations, which it has been identified, require further investigation.

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Abstract B64: Analysis of somatic copy number alterations among African American patients with multiple myeloma using array CGH

10.1158/1055-9965.disp-10-b64 ◽

2010 ◽

Author(s):

Angela S. Baker ◽

Michael Chapman ◽

Esteban Braggio ◽

Jonathan Keats ◽

Bunmi Mfuko ◽

...

Keyword(s):

Multiple Myeloma ◽

African American ◽

Copy Number ◽

Array Cgh ◽

Copy Number Alterations ◽

Somatic Copy Number Alterations

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Genomic DNA Copy Number Alterations Present in AML Bone Marrow Samples with Normal Cytogenetics.

Blood ◽

10.1182/blood.v104.11.142.142 ◽

2004 ◽

Vol 104 (11) ◽

pp. 142-142 ◽

Cited By ~ 1

Author(s):

Matthew J. Walter ◽

Rhonda E. Ries ◽

Jon Armstrong ◽

Brian O’Gara ◽

James W. Vardiman ◽

...

Keyword(s):

Bone Marrow ◽

Copy Number ◽

Genomic Dna ◽

Array Cgh ◽

Comparative Genomic ◽

Copy Number Alterations ◽

Dna Copy Number ◽

Prognostic Information ◽

Normal Cytogenetics ◽

Copy Number Changes

Abstract Cytogenetics and comparative genomic hybridization (CGH) have been used to identify large genomic amplifications and deletions in all subtypes of acute myeloid leukemia (AML). Up to 15–20% of AML patients have a normal karyotype at diagnosis. While cytogenetic abnormalities confer important prognostic information for patients with AML, there remain differences in the therapeutic response and outcome among patients with the same cytogenetic profile, implying that other, more subtle, genetic abnormalities may exist. We hypothesized that a subset of AML patients with normal cytogenetics may contain genomic DNA copy number changes that are too small to be detected using standard cytogenetic techniques. To address this possibility, we used high-resolution bacterial artificial chromosome (BAC) array CGH technology to examine 31 AML patients with normal cytogenetics. The BAC arrays contain 2,464 BAC clones spotted in triplicate on glass slides, and provide a 1 Mb resolution of the entire human genome. Technical generation of the arrays, hybridization parameters, and analysis were similar to that reported for murine BAC array CGH (Nat Genet. 2001 Dec;29(4):459–64). The 31 AML samples included 4 M0, 8 M1, 10 M2, and 9 M4 patients. Array CGH experiments were performed using 500 nanograms of Cyanine 5 labeled genomic DNA from unmanipulated AML bone marrow, mixed with an equal amount of control DNA (a pool of DNA from 4 cancer-free individuals) labeled with Cyanine 3. Using the human 1 Mb BAC arrays, we identified amplifications and deletions from multiple samples that were confirmed with G-banding cytogenetics [del(7)(q31), del(7)(p11.2), +8, del(11)(q13q23), +21, add(21)(q22), −X, −Y, +Y]. In addition, BAC arrays robustly detected copy number alterations that were identified in as few as 4/21 metaphases. We identified 5/31 (16%) patients with normal cytogenetics that contained altered genomic DNA copy numbers using BAC array CGH. Copy number changes were confirmed for several of these genomic loci using a dye-swap experiment, where the AML DNA was labeled with Cyanine 3, and the control DNA with Cyanine 5. Two of the 5 patients with abnormalities detected using array CGH would be reclassified from “intermediate” to “unfavorable” cytogenetics [del(7)(q31.31q34), add(11)(q23.3qter), and 17(p12pter)]. These results suggest that a subset of AML patients with normal cytogenetics contain genomic copy number alterations that may effect treatment and outcome. Patient # FAB subtype Genomic location Gain or loss Size (Megabase) Dye-Swap confirmed 1 M0 7(q31.31q34) loss 2.0 Not done 1 11(q23.3qter) gain 16.5 Not done 2 M1 11(p14) loss 7.4 Yes 3 M1 11(q13.2q14.1) gain 15.8 Yes 3 19(p) gain 64.0 Yes 4 M2 17(p12pter) gain 8.6 Not Done 5 M2 19(p13.1pter) loss 14.8 Yes 5 12(q13) loss 5.0 Yes

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Novel DNA Copy Number Changes in Hematological Malignancies: A cDNA-Based CGH Microarray Screening of CML, AML and CLL Cases without Chromosomal Imbalances in G-Banding.

Blood ◽

10.1182/blood.v104.11.4418.4418 ◽

2004 ◽

Vol 104 (11) ◽

pp. 4418-4418

Author(s):

Tuija Lundan ◽

Anne Oikarainen ◽

Lena Hafren ◽

Maija Wolf ◽

Erkki Elonen ◽

...

Keyword(s):

Copy Number ◽

Myeloid Leukemia ◽

Array Cgh ◽

Reference Sample ◽

Copy Number Alterations ◽

Dna Copy Number ◽

Chromosomal Imbalances ◽

Single Allele ◽

Dna Copy Number Alterations ◽

Copy Number Changes

Abstract Copy number changes, such as small single allele losses and gains, have important roles in the mechanisms of cancer development. These alterations also have often prognostic significance. Genome wide screening of DNA copy number losses previously conducted by extensive LOH analyses can now be performed with array-based comparative genomic hybridization (array CGH). We assessed the utility of array CGH in the detection of single allele deletions and gains in a cohort of seven patients with chronic myeloid leukemia (CML), seven patients with chronic lymphatic leukemia (CLL) and three patients with acute myeloid leukemia (AML). All the CLL and AML patients had a normal karyotype as assessed by standard G-banding. In CML patients the only clonal abnormality detected by cytogenetics was the reciprocal Philadelphia translocation, t(9;22)(q34;q11). The derivative chromosome 9 [der(9)] deletion status of the CML patients was determined using fluorescence in situ hybridization (FISH) analysis. Four patients did not have the deletion, two had a der(9) deletion spanning both 5′ABL and 3′BCR regions and one patient had a deletion of the 5′ABL region alone. The array CGH experiments were performed using Agilent Technologies Human 1 cDNA microarray slides consisting of 13,000 clones. A total of 6 ug of fluorescently labeled DNA extracted from bone marrow samples was hybridized on cDNA array. Normal male or female DNA was used as the reference sample in the hybridization. The slides were scanned with the Agilent fluorescent scanner and intensity ratio data between the tumor and reference sample was processed using Feature Extraction software. The data was filtered and analyzed using SPSS (version 11) and Origin 7.0 softwares. The processed, untransformed red-to-green fluorescence signal ratio was used for evaluating gene dosage. Ratios greater than 1.1 were considered to indicate DNA copy number gains and ratios below 0.9 DNA copy number losses in tumor samples. In two CML patients who had deletions covering both the 5′ABL and 3′BCR regions in the translocation breakpoint of der(9), the deletion was detectable with the array CGH. In four patients with no deletion the red-to-green ratio profile for der(9) was 1. However, in one patient with an isolated 5′ABL deletion, the deletion was not visible in array CGH. No other obvious DNA copy number alterations were seen in CML patients. Array CGH detected deletions in three of the seven CLL patients. Deletions were found in 13q14, 2q32-33 and 14q24. One of the three AML patients studied showed an amplification in chromosome 9p. No alterations were seen in the other two AML patients. The FISH and array studies are being done on larger set of patient samples to confirm the results. We conclude that array CGH provides new information in patients without chromosomal imbalances in standard cytogenetics and enables the detection of novel small submicroscopic copy number alterations. Furthermore, a cDNA-based array platform can be used both for studies of DNA copy number alterations and gene expression analyses.

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Significance of Copy Number Alterations for Molecular Treatment Response in Childhood Acute Lymphoblastic Leukemia.

Blood ◽

10.1182/blood.v110.11.1434.1434 ◽

2007 ◽

Vol 110 (11) ◽

pp. 1434-1434

Author(s):

Doris Steinemann ◽

Gunnar Cario ◽

Martin Stanulla ◽

Leonid Karawajew ◽

Marcel Tauscher ◽

...

Keyword(s):

Acute Lymphoblastic Leukemia ◽

Treatment Response ◽

Copy Number ◽

Array Cgh ◽

Residual Disease ◽

Lymphoblastic Leukemia ◽

Individual Treatment ◽

Copy Number Alterations ◽

Childhood All ◽

Significant Difference

Abstract In vivo response to initial therapy, as assessed by determination of minimal residual disease after five and 12 weeks of treatment, has evolved as one of strong prognostic factors in children with acute lymphoblastic leukemia (ALL) treated according to the BFM regime. It is currently not known if the individual treatment response might be influenced by copy number alterations (CNA) leading to altered gene expression. We compared leukemic genomic profiles of 25 treatment sensitive (MRD-SR) and 25 resistant (MRD-HR) childhood ALL patients by means of high-resolution array-CGH. CNA were found in 46 patients (92%) of both treatment response groups. Microscopic alterations affecting the whole or nearly whole chromosome arm were frequently found, e.g. gain of 21 in 11/50, loss of 9p in 5/50, loss of 8p in 3/50, loss of 20q in 3/50 and loss of 7p in 2/50 or gain of 1q in 2/50. The most significant difference was a gain of chromosome 1q23-qter due to an unbalanced t(1;19), found in 10/25 MRD-SR patients, but in none of the MRD-HR patients (p<0.002). The most frequent CNA in the MRD-HR group were deletions of genomic regions harboring the immunoglobulin genes (Ig), e.g. 2p11.2 in 15 of 25 cases (60%) compared to 7 of 25 in the MRD-SR group (28%) (p=0.045). Combining all Ig loci, significantly more MRD-HR than MRD-SR patients were affected with deletions (17 versus 8 patients, p=0.02). The frequency of other CNA, like loss of 9p21 or gains of 21q, did not differ strongly between the two patient groups. This is the first study evaluating the clinical significance of CNA as detected by array-CGH in childhood ALL and may lead to improved risk classification.

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Targeted Oligonucleotide Array Assessment of Genomic Copy Number Alterations for Risk Stratification in Chronic Lymphocytic Leukemia

Blood ◽

10.1182/blood.v118.21.1773.1773 ◽

2011 ◽

Vol 118 (21) ◽

pp. 1773-1773

Author(s):

Jane Houldsworth ◽

Asha Guttapalli ◽

Xiao J. Yan ◽

Charles Ma ◽

Weiyi Chen ◽

...

Keyword(s):

Risk Stratification ◽

Copy Number ◽

Array Cgh ◽

Lymphocytic Leukemia ◽

P Value ◽

Copy Number Alterations ◽

Mutation Status ◽

Copy Number Changes ◽

Gain Loss ◽

Genomic Regions

Abstract Abstract 1773 Risk stratification in chronic lymphocytic leukemia (CLL) is highly desirable and should comprise not only evaluation of clinical features but also molecular prognostic markers. Currently such molecular markers include loss of 17p13, 11q22, 13q14, 6q22, and gain of chromosome 12 as assessed by fluorescence in situ hybridization (FISH) and mutation status of the variable region of the IGH gene (IGHV) by sequencing. In recent years, genome-wide scanning technologies such as array-comparative genomic hybridization (array-CGH) have revealed novel and refined known copy number alterations (CNAs) in the CLL genome. In order to evaluate the potential of array-CGH in prognostication in mature B-cell neoplasms, including CLL, and implement array-CGH in a clinical diagnostic laboratory, a targeted oligonucleotide-based microarray was custom designed to represent genomic regions exhibiting gain/loss in these lymphoid neoplasms. The 4 × 44K formatted array included 2 × 17,348 probes for the 80 selected genomic regions (average resolution of 34kbp), and recommended controls including a 1Mbp genome backbone. DNA extracted from two CLL datasets were submitted to array-CGH using an equimixture of commercially available male/female DNA as a reference. CNAs were detected using Genomics Workbench Lite (Agilent Technologies, Inc.) with the ADM2 algorithm. Analytical sensitivity was assessed by cell line DNA dilution and by FISH (116 specimens) and was 30–40% and 20–25%, respectively. Recurrent CNAs in previously untreated patients, greater than 1.5Mbp in size, were analyzed for association with time to first treatment (TTFT) and overall survival (OS) by the log rank test. Association with IGHV mutation status was tested using the Fisher's two-sided exact test. In both datasets for untreated specimens, unmutated IGHV negatively correlated with both TTFT and OS significantly (p < 0.05). Gain of chromosome 12 was detected in 11–12% of untreated specimens in both datasets and as expected did not associate with outcome. Loss of 13q14 as a sole abnormality (excluding copy number changes arising at known sites of normal variation) was associated with an overall favorable outcome, but specimens with loss of both loci (MIR15A/16-1 and RB1) versus one locus (MIR15A/16-1) did not display significantly different outcomes. As expected loss of 17p13 associated with shorter TTFT and OS, and was observed at higher levels in treated specimens. A similar result was observed for 11q22 loss but not in the second dataset, perhaps due to the relatively short follow-up time. Importantly, four additional copy number changes (gain of 2p, 3q, and 8q, and loss of 8p) were found to associate with shorter TTFT and/or OS, and also occurred at higher frequency in treated specimens. Notably, all but one specimen exhibiting two of these CNAs, were Rai Stage 0-II. After multiple comparisons correction, gain of 2p and 3q, and loss of 8p remained significantly associated with an unfavorable outcome. Gain of 2p25.3-p15 was observed exclusively in unmutated IGHV specimens. Loss of 18p and gain of 17q24 were not considered further for testing due to low frequency or lower frequency in treated specimens (data not shown). Uniquely, these data demonstrate in low-intermediate risk CLL cohorts the prognostic value of genomic gain/loss at multiple sites and support implementation of array-CGH into a clinical setting for risk stratification in CLL where genomic gain or loss of multiple clinically relevant genomic regions can be assessed simultaneously. Dataset 1 Untreated n = 81 TTFT p-value OS p-value Treated n = 38 Dataset 2 n = 169 TTFT p-value OS p-value Treated n = 28 Median TTFT 87.6 mo 24.1 mo Median OS 117.7 mo 37.2 mo Rai Stage 0 25 77 I-II 42 48 III-IV 5 1 na 9 43 Unmutated IGHV 46% (n=80) 0.0003 0.0004 38% (n=163) 0.002 0.044 13q14 loss (sole abnormality) 52.5% 0.038‡ 0.087‡ 33.7% 0.144‡ 0.008‡ MIR15A/16-1, RB1 27.5% 0.77 0.337 11.2% 0.011 1 MIR15A/16-1 25.0% 22.5% 11q22 loss (ATM) 12.3% 0.125 0.009 23.7% 8.3% 0.393 0.977 14.3% 17p13 loss (TP53) 2.5% 0.010 0.012 15.8% 4.7% 0.006 <.0001 10.7% 2p25.3-p15 gain 6.2% 0.002 <.0001 10.5% 3.0% 0.702 0.025 10.7% 8q24 gain 2.5% 0.238 0.014 7.9% 4.1% 0.564 0.007 0.0% 3q26-q27 gain 2.5% <.0001 <.0001 5.3% 3.0% 0.850 <.0001 7.1% 8p23-p21 loss 2.5% 0.002 0.016 10.5% 1.2% 1 <.0001 7.1% Unless otherwise noted, all values associated with shorter times ‡ Associated with longer time na not available Disclosures: Houldsworth: Cancer Genetics, Inc.: Employment. Guttapalli:Cancer Genetics, Inc.: Employment. Ma:Cancer Genetics, Inc.: Employment. Chen:Cancer Genetics, Inc.: Employment. Patil:Cancer Genetics, Inc.: Consultancy.

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Oligonucleotide array-CGH reveals cryptic gene copy number alterations in karyotypically normal acute myeloid leukemia

Leukemia ◽

10.1038/sj.leu.2404543 ◽

2007 ◽

Vol 21 (3) ◽

pp. 571-574 ◽

Cited By ~ 38

Author(s):

A Tyybäkinoja ◽

E Elonen ◽

K Piippo ◽

K Porkka ◽

S Knuutila

Keyword(s):

Acute Myeloid Leukemia ◽

Copy Number ◽

Myeloid Leukemia ◽

Array Cgh ◽

Gene Copy Number ◽

Oligonucleotide Array ◽

Gene Copy ◽

Copy Number Alterations ◽

Acute Myeloid

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Genomic Profiling helps to Predict Treatment Response and Outcome in Relapsed Childhood ETV6/RUNX1-Positive Acute Lymphoblastic Leukemia.

Blood ◽

10.1182/blood.v112.11.1485.1485 ◽

2008 ◽

Vol 112 (11) ◽

pp. 1485-1485

Author(s):

Almut Giese ◽

Reinhard Ullmann ◽

Cornelia Eckert ◽

Renate Kirschner-Schwabe ◽

Guenter Henze ◽

...

Keyword(s):

Acute Lymphoblastic Leukemia ◽

High Resolution ◽

X Chromosome ◽

Copy Number ◽

Array Cgh ◽

Lymphoblastic Leukemia ◽

Response To Treatment ◽

Genomic Profiling ◽

Copy Number Alterations ◽

Genetic Aberrations

Abstract The ETV6/RUNX1 fusion, resulting from the cryptic translocation t(12;21)(p13;q22), is the most common genetic rearrangement in B-cell precursor (BCP) acute lymphoblastic leukemia (ALL) with a prevalence of approximately 20–25% at first presentation. Although generally associated with favorable risk features and advantageous long-term survival rates, similar frequencies of ETV6/RUNX1 positivity at relapse question its prognostic significance. At relapse, a second continuous complete remission can again be achieved in the majority of patients with ETV6/RUNX1-positive ALL, however, a substantial proportion (approximately 25%) exhibit a poor response to treatment and eventually experience a subsequent relapse. Currently, critical secondary genetic events are assumed to be pivotal for t(12;21) positive ALL leukemogenesis. At the chromosomal level, additional numeric aberrations may also contribute to differences both in treatment response and course of disease, and may provide additional prognostic information. Aiming at identifying the incidence and the clinical relevance of additional genetic aberrations at the time point of first ALL relapse diagnosis, we performed whole genome high resolution tiling-path bacterial artificial chromosome (BAC) array CGH of leukemic cell DNA from 53 patients with ETV6/RUNX1-positive first relapse enrolled in the relapse trials ALL-REZ BFM of the Berlin-Frankfurt-Münster study group. Additional genetic aberrations were detected in all of the ETV6/RUNX1-positive leukemic bone marrow samples with a mean number of seven aberrations per ALL. Chromosomal losses were observed approximately 2.5 times more frequently than gains. A high proportion of the identified copy number alterations occurred in recurrently affected chromosomal regions. Copy number alterations most commonly detected by high-resolution array CGH were losses of 12p13 (49%, 26/53), 6q21 (34%, 18/53), 15q15.1 (23%, 12/53), 9p21 (21%, 11/53), 3p21 (21%, 11/53), 5q (19%, 10/53), 19q13 (17%, 9/53), 10q (13%, 7/53), 3p14.2 (11%, 6/53) and gains of 21q22 (32%, 17/53) and of 12p (21%, 11/53). Loss of the whole X-chromosome, detected in 17% (9/53) of the analyzed samples, was observed exclusively in females. In contrast, gain of Xq, identified in 13% (7/53) of the samples, was detectable solely in males. Evaluation of the clinical parameters in relation to recurrent copy number alterations revealed that loss of the whole X-chromosome was associated with a molecular good response to treatment (P=0.03), as assessed by sensitive minimal residual disease (MRD) monitoring. In contrast, loss of 5q31.3, detected in 11% (6/53) of the analyzed samples, was associated with a dismal molecular response to therapy (P=0.019) and with a tendency to a worse outcome (P=0.054). Thus, this study demonstrates that relapsed ETV6/RUNX1-positive ALL is characterized by (a.) multiple additional genomic alterations, in particular by a high incidence of chromosomal losses, which occur predominantly in recurrently affected chromosomal regions, some of which (b.) are of significant prognostic relevance. These findings support the notion that several additional chromosomal changes are not only required for the process of malignant transformation in ETV6/RUNX1-positive ALL (leukemogenesis) but also influence therapeutic success. Perspectively, high resolution genomic profiling will provide valuable information enabling a more refined, individualized therapy and an improved risk stratification in relapsed childhood ALL.

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