SNP-based arrays complement classic cytogenetics in the detection of chromosomal aberrations in Wilms' tumor

Wilms' tumors have characteristic chromosomal abnormalities, such as the 11p13 deletion, in a subset of cases. This is one of the very few reports comparing single nucleotide polymorphism (SNP) array analysis with conventional karyotyping of Wilms' tumors. A total of 43 frozen tumor samples were analyzed using the Affymetrix Cytogenetics Whole-Genome 2.7M array. The findings from the SNP array analysis were then compared with those from conventional karyotyping. A comparison between SNP array and conventional karyotype findings was possible in 38 of 43 specimens (88.4%). The SNP array and classic cytogenetic results were concordant in 33 of 38 specimens (87%). SNP array analysis was able to support the findings of classic cytogenetics. The SNP array detected regions of loss of heterozygosity (LOH) in 41 of 43 (95%) specimens. However, it did not detect balanced translocations and inversions that were observed by conventional cytogenetics. Our results show that the data generated from these platforms are complementary. The SNP array also detected additional gains and losses as well as regions of LOH with associated disomy, which are likely to represent segmental uniparental disomy. The observed discrepancies can be explained by the inherent limitations of each technique.     

Integration of microarray analysis into the clinical diagnosis of hematological malignancies: How much can we improve cytogenetic testing?

Purpose

To evaluate the clinical utility, diagnostic yield and rationale of integrating microarray analysis in the clinical diagnosis of hematological malignancies in comparison with classical chromosome karyotyping/fluorescence in situ hybridization (FISH).

Methods

G-banded chromosome analysis, FISH and microarray studies using customized CGH and CGH+SNP designs were performed on 27 samples from patients with hematological malignancies. A comprehensive comparison of the results obtained by three methods was conducted to evaluate benefits and limitations of these techniques for clinical diagnosis.

Results

Overall, 89.7% of chromosomal abnormalities identified by karyotyping/FISH studies were also detectable by microarray. Among 183 acquired copy number alterations (CNAs) identified by microarray, 94 were additional findings revealed in 14 cases (52%), and at least 30% of CNAs were in genomic regions of diagnostic/prognostic significance. Approximately 30% of novel alterations detected by microarray were >20 Mb in size. Balanced abnormalities were not detected by microarray; however, of the 19 apparently “balanced” rearrangements, 55% (6/11) of recurrent and 13% (1/8) of non-recurrent translocations had alterations at the breakpoints discovered by microarray.

Conclusion

Microarray technology enables accurate, cost-effective and time-efficient whole-genome analysis at a resolution significantly higher than that of conventional karyotyping and FISH. Array-CGH showed advantage in identification of cryptic imbalances and detection of clonal aberrations in population of non-dividing cancer cells and samples with poor chromosome morphology. The integration of microarray analysis into the cytogenetic diagnosis of hematologic malignancies has the potential to improve patient management by providing clinicians with additional disease specific and potentially clinically actionable genomic alterations.     

Comprehensive cytogenetic study of primary cutaneous gamma-delta T-cell lymphoma by means of spectral karyotyping and genome-wide single nucleotide polymorphism array

Primary cutaneous gamma-delta T-cell lymphoma (PCGD-TCL), which originates from activated mature gamma-delta T cells with a cytotoxic phenotype is a rare T-cell lymphoproliferative disease. The prognosis of PCGD-TCL has been rather unfavorable due to poor response to conventional chemotherapy, and its molecular features and pathophysiology underlying disease development remain unknown. We report here a case with primarily treatment-resistant PCGD-TCL featuring highly complex cytogenetic and genetic aberrations detected by spectral karyotyping and genome-wide single nucleotide polymorphism (SNP) array. Chromosomal aberrations included several chromosomal translocations involving breakpoints at 9p21, 14q11.2, 14q32.1, or 16q23.1, suggesting the involvement of WWOX, TCL gene cluster, and BCL11B, which are crucial for tumorigenesis in T-cell lymphomas. SNP analysis also identified genome copy number gains and losses in various regions, which can potently deregulate expression of various pro- and anti-oncogenic genes involved in RAS-related protein pathways, PI3K/AKT/MTOR-related pathways, MYC-related signaling, or TP53-related signaling. Thus, this case report may shed some light on the complex molecular abnormalities involved in the development of PCGD-TCL and on information that can aid the search for druggable target molecules in this disease.     

Clinical utilization of high-resolution single nucleotide polymorphism based oligonucleotide arrays in diagnostic studies of pediatric patients with solid tumors

High-resolution single nucleotide polymorphism (SNP) arrays have been effectively implemented as a first tier test in clinical cytogenetics laboratories for the detection of constitutional chromosomal abnormalities in patients with suspected genomic disorders. We recently published our experience utilizing SNP array analysis of bone marrow aspirates as a clinical test for patients with suspected leukemia or lymphoma in the Clinical Cancer Cytogenetics Laboratory at The Children's Hospital of Philadelphia. In the present report we summarize our clinical experience using the Illumina HumanHap610 BeadChip array (Illumina, San Diego, CA) for whole genome analysis of pediatric solid tumors. A total of 168 DNA samples isolated from a variety of solid tumors, including brain tumors, sarcomas, neuroblastomas, and Wilms tumors, as well as benign neoplasms and reactive processes, were analyzed over a 2 1/2 year period. One hundred thirty-seven of 168 (82%) specimens had at least one copy number alteration or region of loss of heterozygosity detected by the SNP array. Thirty-three of 168 (20%) of cases had a normal karyotype or targeted fluorescence in situ hybridization (FISH) study, but had an abnormal finding by the array analysis. Sixty-three of 168 (37%) samples for which cytogenetic studies were unsuccessful or not performed demonstrated an abnormal array result. In 44 of 168 cases (26%) the array and karyotype or FISH were abnormal, but each demonstrated alterations not detected by the other methodology. Based on our experience in the last 2 1/2 years, we suggest that SNP array analysis can be used as a first tier clinical test for the majority of pediatric solid tumors.     

Comprehensive genotypic analysis of leukemia: clinical and therapeutic implications.

Over the past several years, the application of a spectrum of cytogenetic and molecular diagnostic techniques has dramatically improved our understanding of the pathophysiology of leukemia. These techniques include chromosomal translocations visualized by G-banding techniques, fluorescence in-situ hybridization, spectral karyotyping, comparative genomic hybridization, loss of heterozygosity analysis, and characterization of point mutations by DNA sequence analysis. We will review the application of these techniques, update novel findings utilizing these techniques over the past year as they apply to specific leukemias, and review the clinical and therapeutic implications of these findings.     

Single-nucleotide polymorphism array karyotyping in clinical practice: where, when, and how?

Single-nucleotide polymorphism array (SNP-A) karyotyping is a new technology that has enabled genome-wide detection of genetic lesions in human cancers, including hematopoietic neoplasms. Taking advantage of very large numbers of allele-specific probes synthesized on microarrays at high density, copy number alterations as well as allelic imbalances can be sensitively detected in a genome-wide manner at unprecedented resolutions. Most importantly, SNP-A karyotyping represents the only platform currently available for genome-scale detection of copy neutral loss of heterozygosity (CN-LOH) or uniparental disomy (UPD), which is widely observed in cancer genomes. Although not applicable to detection of balanced translocations, which are commonly found in hematopoietic malignancies, SNP-A karyotyping technology complements and even outperforms conventional metaphase karyotyping, potentially allowing for more accurate genetic diagnosis of hematopoietic neoplasms in clinical practice. Here, we review the current status of SNP-A karyotyping and its application to hematopoietic neoplasms.     

Comparative Genomic Hybridization and Conventional Cytogenetic Analyses in Childhood Acute Myeloid Leukemia

Comparative genornic hybridization (CGH) analysis was performed on bone marrow specimens from 19 children with acute myeloid leukemia (AML) at diagnosis. The results of CGH were compared to those of conventional cytogenetic analysis. The most common CGH aberrations were gains of whole chromosomes 6 and 8, both of which appeared three times. Two losses were seen twice; losses of whole chromosomes 7 and X. The CGH findings were concordant with the results of conventional karyotyping. CGH did not add new information to the karyotypes. Since no high-level amplification was found among the samples and standard karyotyping was highly successful, we do not advocate routine use of CGH in the diagnostic evaluation of childhood AML.     

Comparative genomic hybridization and conventional cytogenetic analyses in childhood acute myeloid leukemia

Comparative genomic hybridization (CGH) analysis was performed on bone marrow specimens from 19 children with acute myeloid leukemia (AML) at diagnosis. The results of CGH were compared to those of conventional cytogenetic analysis. The most common CGH aberrations were gains of whole chromosomes 6 and 8, both of which appeared three times. Two losses were seen twice; losses of whole chromosomes 7 and X. The CGH findings were concordant with the results of conventional karyotyping. CGH did not add new information to the karyotypes. Since no high-level amplification was found among the samples and standard karyotyping was highly successful, we do not advocate routine use of CGH in the diagnostic evaluation of childhood AML.     

The prognostic significance of cytogenetics and molecular profiling in multiple myeloma

Multiple myeloma (MM) is a plasma cell malignancy characterized by very complex cytogenetic and molecular genetic aberrations. In newly diagnosed symptomatic patients, the modal chromosome number is usually either hyperdiploid with multiple trisomies or hypodiploid with one of several types of immunoglobulin heavy chain (Ig) translocations. The chromosome ploidy status and Ig rearrangements are two genetic criteria that are used to help stratify patients into prognostic groups based on the findings of conventional cytogenetics and fluorescence in situ hybridization (FISH). In general, the hypodiploid group with t(4;14)(p16;q32) or t(14;16)(q32;q23) is considered a high-risk group, while the hyperdiploid patients with t(11;14)(q13;q32) are considered a better prognostic group. As the disease progresses, it becomes more proliferative and develops a number of secondary chromosome aberrations. These secondary aberrations commonly involve MYC rearrangements, del(13q), del(17p), and the deletion of 1p and/or amplification of 1q. Of the secondary aberrations, del(17p) is consistently associated with poor prognosis. All of these cytogenetic aberrations and many additional ones are now identified by means of high resolution molecular profiling. Gene expression profiling (GEP), array comparative genomic hybridization (aCGH), and single-nucleotide polymorphism (SNP) arrays have been able to identify novel genetic aberration patterns that have previously gone unrecognized. With the integration of data from these profiling techniques, new subclassifications of MM have been proposed which define distinct molecular genetic subgroups. In this review, the findings from conventional cytogenetics, interphase FISH, GEP, aCGH, and SNP profiles are described to provide the conceptual framework for defining the emerging molecular genetic subgroups with prognostic significance.     

Detailed chromosomal characterization of the breast cancer cell line MCF7 with special focus on the expression of the serine-threonine kinase 15

Although the cell line MCF7 is widely used in breast cancer research, its cytogenetic properties have not been thoroughly investigated so far. As conventional G-banding analysis cannot resolve the complex chromosome aberrations, we investigated MCF7 cells using molecular-cytogenetic methods, with particular attention to the DNA amplification site on chromosome 20q. With spectral karyotyping we found numerous unbalanced chromosome translocations, and with comparative genomic hybridization we detected many quantitative genomic imbalances. Furthermore, we analyzed the amplified region at 20q with the candidate tumour susceptibility gene STK15 in detail by fluorescence in situ hybridization, whole chromosome painting, immunohistochemistry, Western blot and expression analysis. In MCF7 interphase cells we found increased copy number of the STK15 gene associated with overexpression of STK15 mRNA. Accordingly, STK15 protein is overexpressed as compared to normal human fibroblasts in Western blot analysis. Overexpression of STK15 mRNA and protein is disproportionally stronger than that expected from the single additional copy of the STK15 gene. These data indicate that the highly increased level of STK15 protein in MCF7 cannot be explained by gene amplification alone. Apparently, secondary mechanisms of gene up-regulation are involved. This observation may be of general interest with regard to the activation of oncogenes in tumour cells.     

High resolution genomic profiling and classical cytogenetics in a group of benign and atypical meningiomas

Meningiomas are classified as benign, atypical, or anaplastic. The majority are sporadic, solitary, and benign tumors with favorable prognoses. However, the prognosis for patients with anaplastic meningiomas remains less favorable. High resolution genomic profiling has the capacity to provide more detailed information. Therefore, we analyzed genomic aberrations of benign and atypical meningiomas using single nucleotide polymorphism (SNP) array, combined with G-banding by trypsin using Giemsa stain (GTG banding), spectral karyotyping, and locus-specific fluorescence in situ hybridization (FISH). We confirmed frequently detected chromosomal aberrations in meningiomas and identified novel genetic events. Applying SNP array, we identified constitutional de?novo loss or gain within chromosome 22 in three patients, possibly representing inherited causal?events for meningioma formation. We show evidence for somatic segmental uniparental disomy in regions 4p16.1, 7q31.2, 8p23.2, and 9p22.1 not previously described for primary meningioma. GTG-banding and spectral karyotyping detected a novel balanced reciprocal translocation t(4;10)(q12;q26) in one benign meningioma. A paracentric inversion within 1p36, previously described as?novel, was detected as a recurrent chromosomal aberration in benign and atypical meningiomas. Analyses of tumors and matched normal tissues with a combination of SNP arrays and complementary techniques will help to further elucidate potentially causal genetic events for tumorigenesis of meningioma.     

High-throughput genomic analysis in Waldenström's macroglobulinemia

Single-nucleotide polymorphism array (SNPa) and array-based comparative genomic hybridization (aCGH) are among the most sensitive genomic high-throughput screening techniques used in the exploration of genetic abnormalities in Waldenström's macroglobulinemia (WM). SNP and aCGH allow the identification of copy number abnormalities (CNA) at the kilobase level thus identifying cryptic genetic abnormalities unseen by lower-resolution approaches such as conventional cytogenetic or fluorescence in situ hybridization (FISH). CNA were identified in nearly 80% of cases by aCGH that delineated in addition minimal altered regions. At gene level, remarkable findings affecting genes involved in the regulation of the NF-kB signaling pathways were identified, such as biallelic inactivation of TNFAIP3 and TRAF3. SNPa also allowed characterization of copy neutral losses such as uniparental disomies (UPD), which is an important and frequent mechanism of gene alteration in cancer cells. Herein, we summarize the current knowledge of WM genomic basis using these high-throughput techniques.     

Usefulness of cytogenetics in leukemias

Present study consists of cytogenetic evaluation in 141 cases referred to our centre for various leukemias. This includes 110 cases of CML, 10 of ALL, 16 of AML (M3), 2 of AML(M2), 2 of MDS and 1 of CMML. The conventional cytogenetic study was carried out in all the cases using G Banding technique. Of the 141 patients studied, 17 patients showed secondary chromosomal alterations along with primary chromosomal alterations. In two patients of CML with secondary chromosomal alteration t(4:9:22), molecular cytogenetic technique (FISH) has been carried out which has confirmed the primary observations revealed by the conventional cytogenetic technique. Other secondary alterations were numerous and would have been missed if only FISH or PCR technique would have been used for diagnosis. We observed from our study that advanced molecular techniques like FISH and PCR cannot replace the conventional cytogenetic study but are useful as supportive and confirmative diagnostic tools.     

Translocation t(2;3)(p15-23;q26-27) in myeloid malignancies: report of 21 new cases, clinical, cytogenetic and molecular genetic features.

Chromosomal rearrangements involving 3q26 either due to inversion or translocation with various partner chromosomes are a recurrent finding in malignant myeloid disorders. Typically, these chromosome aberrations contribute to ectopic expression of or to the formation of fusion genes involving the EVI1 proto-oncogene. Chromosomal translocations involving the short arm of chromosome 2 (p15-p23) and the distal part of the long arm of chromosome 3 (q26-q27) are a rare but recurrent finding in patients with myeloid malignancies, and are assumed to be part of this spectrum of disorders. Thus far, however, these translocations have been poorly studied. Here, we present 21 new cases with myelodysplasia, acute myeloid leukemia or CML in blast crisis, which upon karyotyping showed the presence of a t(2;3). Furthermore, an extensive literature review disclosed 29 additional cases. Morphological, clinical and cytogenetic assessment revealed the typical hallmarks of 3q26/EVI1 rearrangements, that is, trilineage dysplasia and dysmegakaryopoiesis, poor prognosis and additional monosomy 7. Molecular cytogenetic analysis and PCR in selected samples indicated that in most cases the translocation indeed targets the EVI1 locus. Mapping of the chromosome 2 breakpoints confirmed the initially suspected cytogenetic breakpoint heterogeneity at the 2p arm.     

儿童急性淋巴细胞白血病TEL-AML1融合基因检测

 目的　检测儿童急性淋巴细胞白血病（ALL）中TEL-AML1融合基因的阳性率,探讨TEL-AML1融合基因的检测方法及其临床应用价值。方法　在形态学、免疫分型、细胞遗传学基础上,采用巢式反转录-聚合酶链反应（RT-PCR）和荧光原位杂交技术（FISH）检测31例ALL患儿骨髓单核细胞中TEL-AML1融合基因。结果　巢式RT-PCR技术和FISH技术均可以显著提高TEL-AML1融合基因的检出率,应用上述两种方法,31例患儿中检测出7例TEL-AML1阳性,占儿童初发ALL的22.6 %（7／31）,在B系ALL中的阳性率为25.9 %（7／27）。结论　t(12;21)形成TEL-AML1融合基因是儿童ALL最常见的染色体易位,常规染色体核型分析极难发现,需用巢式RT-PCR或FISH等分子检测方法加以证实。     

Computational analysis of flow-cytometry antigen expression profiles in childhood acute lymphoblastic leukemia: an MLL/AF4 identification.

Precursor B-acute lymphoblastic leukemia (pB-ALL) is a heterogeneous disease and multiparameter flow cytometry, molecular genetics, and cytogenetic studies have all contributed to classification of subgroups with prognostic significance. Recently, gene expression microarray technology has been used to investigate lymphoblastic leukemias, demonstrating that known and novel pB-ALL subclasses can be separated on the basis of gene expression profiles. The strength of microarray technique lays in part in the multivariate nature of the expression data. We propose a parallel multiparametric approach based on immunophenotypic flow-cytometry expression data for the analysis of leukemia patients. Specifically, we tested the potential of this approach on a data set of 145 samples of pediatric pB-ALL that included 46 samples positive for mixed lineage leukemia (MLL) translocations (MLL+) and 99 control pB-ALLs, negative for this translocation (MLL-). The expression levels of 16 marker proteins have been monitored by four-color flow cytometry using a standardized diagnostic panel of antibodies. The protein expression database has been then analyzed using those univariate and multivariate computational techniques normally applied to mine and model large microarray data sets. Marker protein expression profiling not only allowed separating pB-ALL cases with an MLL rearrangement from other ALLs, but also demonstrates that MLL+ leukemias constitute a heterogeneous group in which MLL/AF4 leukemias represent a homogenous subclass described by a specific expression fingerprint.     

Hidden aberrations diagnosed by interphase fluorescence in situ hybridisation and spectral karyotyping in childhood acute lymphoblastic leukaemia

Acute lymphoblastic leukaemia (ALL) is the most common oncologic disease in childhood, accounting for approximately 25% of all paediatric malignancies. Based on clinical risk criteria and modern laboratory investigations including immunophenotyping, cytogenetics and molecular genetics, patients can be divided into prognostic groups and assigned to risk-adjusted treatment protocols. The karyotype is an independent prognostic indicator and has for some aberrations that are associated with a poor outcome a direct impact on the choice of treatment. Cytogenetic analysis in ALL is often hampered by poor chromosome morphology, few malignant metaphases, undetectable chromosomal rearrangements due to regions of a similar size and banding pattern and sometimes only normal metaphases derived from normal cells are found after cell culture. Structural as well as numerical aberrations may therefore remain undetected using conventional G-banding. The application of modern molecular cytogenetic techniques including a broad set of fluorescence in situ hybridisation (FISH) methods and recent developments in comparative genomic hybridisation to DNA microarrays, together with molecular methods such as Southern blotting and RT-PCR has greatly improved the detection rate of genetic changes in ALL. This review emphasises the value of increasing the resolving power of the cytogenetic investigation by spectral karyotyping (SKY) and interphase FISH in identifying prognostically important and novel chromosomal rearrangements as a complement to conventional banding analysis. The results of investigations performed on cases with ALL have shown that interphase FISH is valuable and in many cases even mandatory for the detection of prognostically important genetic abnormalities and should therefore consistently be employed in the routine cytogenetic investigations in ALL. Likewise, SKY is a valuable tool for the cytogenetic analysis. Thus, the results of several different investigations described in this review revealed that SKY yielded additional information in 97/157 (62%) cases with chromosomal aberrations detected by G-banding, and in 10/66 (15%) cases with normal G-banding.     

Multicolor spectral karyotyping identifies novel translocations in childhood acute lymphoblastic leukemia.

We used a recently described molecular cytogenetic method, spectral karyotyping (SKY), to analyze metaphase chromosomes from 30 pediatric patients with acute lymphoblastic leukemia (ALL). This group included 20 patients whose leukemic blast cells lacked chromosomal abnormalities detected by conventional cytogenetics and 10 patients whose blast cells had multiple chromosomal abnormalities that could not be completely identified by G-banding analysis. In two of the 20 patients (10%) with apparently normal karyotypes, SKY identified three cryptic translocations: a t(7;8)(q34-35;q24.1) in one patient and a t(13;17)(q22;q21) and a der(19)t(17;19)(q22;p13) in another. Fluorescence in situ hybridization using subtelomeric probes proved the latter translocation to be a t(17;19). SKY analysis was also successful in defining the nature of the chromosomal abnormalities in four of the 10 patients with marker and derivative chromosomes. The identified abnormalities in the latter group included three novel translocations: a der(X)t(X;5)(p11.4;q31), a der(21)t(X;21)(p11.4;p11.2) and a t(X;9)(p11.4;p13). The presence of the t(X;9) was suggested by conventional cytogenetics. The application of fluorescence in situ hybridization using chromosome-specific painting probes and locus-specific probes complemented the SKY analysis by confirming the nature of the chromosome rearrangements defined by SKY and by identifying the amplification of the AML1/CBFA2 gene in one patient with a duplicated 21q. Our study demonstrates the utility of SKY in identifying novel translocations and in refining the identity of chromosomal abnormalities in leukemias.