Daniël Olde Weghuis

Detection of chromosomal DNA gains and losses in testicular germ cell tumors by comparative genomic hybridization

To extend the results of conventional cytogenetic analysis of testicular germ cell tumors (TGCTs), we applied the new molecular cytogenetic method of comparative genomic hybridization (CGH), which enables the detection of chromosomal imbalances without the need for dividing cells. DNA from II TGCTs was studied by CGH. In all tumors examined, gain of 12p, mostly of the whole p arm, could be demonstrated. However, in three tumors, an amplification of 12p material restricted to the chromosomal bands 12p11.2‐p12.1 was found. Further fluorescence in situ hybridization (FISH) analysis using a yeast artificial chromosome (YAC) that was previously mapped to that region revealed multiple copies of that chromosomal segment in interphase nuclei of these tumors. This finding is an important clue to the localization of candidate protooncogenes at 12p involved in TGCTs. Gains of small chromosomal regions at 2p, 4q, 6p, and 19p were also detected recurrently. Furthermore, gains of chromosomes 8, 14, 21, and X as well as loss of chromosome 13 were frequent findings. In conclusion, CGH provides new insights into genetic alterations of TGCTs. By using CGH, chromosomal subregions could be identified that may harbor genes involved in the pathogenesis of this malignancy. Genes Chromosom Cancer 17:78–87 (1996).

Amplification of chromosome subregion 12p11.2-p12.1 in a metastasis of an I(12p)-negative seminoma: relationship to tumor progression?

Cytogenetic analysis of a metastasis of a human testicular germ cell tumor (seminoma) revealed multiple numerical and structural anomalies, including an abnormally banding region (ABR) present on the short arm of one of the chromosome 12 homologs. Fluorescence in situ- and comparative genomic hybridization experiments revealed that the ABR results from the amplification of 12p11.2-p12.1 derived sequences. We speculate that this particular region may harbor gene(s) relevant for testicular germ cell tumor progression.

T(7;12)(q36;p13) and t(7;12)(q32;p13) - Translocations involving ETV6 in children 18 months of age or younger with myeloid disorders

Our retrospective karyotype review revealed two rare recurrent translocations affecting ETV6 (TEL): t(7;12)(q36;p13) and t(7;12)(q32;p13). Five patients with a t(7;12) were from a group of 125 successfully karyotyped pediatric patients enrolled in consecutive clinical AML trials of the Dutch Childhood Leukemia Study Group over a period of 7 years. During a search of available cytogenetic databases, we found 7q and 12p abnormalities in two additional Dutch patients and in three participants in Pediatric Oncology Group trials. A del(12p) had been initially identified in four of these patients and re-examination of the original karyograms revealed a t(7;12)(q36;p13) in two instances and a probable t(7;12) in the other two. FISH confirmed the presence of a t(7;12)(q36;p13) in the latter. Most (n = 7) also had trisomy 19. The t(7;12)(q36;p13) (n = 9) was more common than the t(7;12)(q32;p13) (n = 1). These subtle translocations were found only in children 18 months of age or younger. A literature search revealed that the t(7;12) with breakpoints at 7q31-q36 and 12p12-p13 had been reported in six children with myeloid disorders and in two with acute lymphoblastic leukemia; all were 12 months of age or younger. Only two of the 17 for whom survival data were available, were alive after at least 22 months of continuous complete remission. Our findings suggest that ETV6rearrangements due to a t(7;12) may play an adverse role in myeloid disorders in children 18 months of age or younger. Therefore, children in this age group with myeloid disorders should be screened for both MLL and ETV6 rearrangements.

Assignment of the human gene for the water channel of renal collecting duct Aquaporin 2 (AQP2) to chromosome 12 region q12→q13

The chromosomal localization of the gene encoding Aquaporin 2 (previously called WCH-CD), which acts as a water channel in the collecting tubules of the kidney, was determined. Southern blot hybridizations of chromosomal DNA from a panel of 25 different human-rodent hybrid cell lines assigned AQP2 to the q-arm of human chromosome 12. Additionally, in situ hybridization on R-banded metaphase chromosomes localized AQP2 to the q12-->q13 region of this chromosome.

Fine mapping of the human renal oncocytoma-associated translocation (5;11)(q35;q13) breakpoint

Recent cytogenetic analysis of a series of human renal oncocytomas revealed the presence of a recurring chromosomal translocation (5;11)(q35;q13) as sole anomaly in a subset of the tumors. The molecular characterization of this translocation was initiated using two primary t(5;11)-positive renal oncocytomas and a panel of somatic cell hybrids derived from one of these tumors, in conjunction with fluorescence in situ hybridization (FISH) and Southern blot analysis. The breakpoint in chromosome band 11q13 could be located within a genomic interval of at maximum 400 Kb immediately centromeric to the BCL1 locus.

Identification of chromosomal abnormalities relevant to prognosis in chronic lymphocytic leukemia using multiplex ligation-dependent probe amplification

B-cell chronic lymphocytic leukemia (CLL) is characterized by a highly variable clinical course. Characteristic genomic abnormalities provide clinically important prognostic information. Because karyotyping and fluorescence in situ hybridization (FISH) are laborious techniques, we investigated the diagnostic efficacy of the more recently developed multiplex ligation-dependent probe amplification (MLPA) technique. MLPA and interphase FISH data of 88 CLL patients were compared for loci encompassing the 13q14 region, chromosome 12, and the ATM (11q22) and TP53 (17p13) genes. We found a perfect correlation, provided that the abnormal clone was present in at least 10-20% of the cells. Because multiple loci and multiple probes per locus were included in the MLPA assay, additional abnormalities not covered by the FISH probes were detected. Furthermore, in 13 cases deletions partly covering the 13q14.3 locus were observed, including three deletions that remained undetected by FISH. All the deletions included the noncoding RNA locus DLEU1 (previously BCMS), which is considered to be the most likely CLL-associated candidate tumor suppressor gene within the 13q14 region. We conclude that MLPA serves as a comprehensive and reliable technique for the simultaneous identification of different clinically relevant and region-specific genomic aberrations in CLL.

Microarray-based genomic profiling as a diagnostic tool in acute lymphoblastic leukemia

In acute lymphoblastic leukemia (ALL) specific genomic abnormalities provide important clinical information. In most routine clinical diagnostic laboratories conventional karyotyping, in conjunction with targeted screens using e.g., fluorescence in situ hybridization (FISH), is currently considered as the gold standard to detect such aberrations. Conventional karyotyping, however, is limited in its resolution and yield, thus hampering the genetic diagnosis of ALL. We explored whether microarray‐based genomic profiling would be feasible as an alternative strategy in a routine clinical diagnostic setting. To this end, we compared conventional karyotypes with microarray‐deduced copy number aberration (CNA) karyotypes in 60 ALL cases. Microarray‐based genomic profiling resulted in a CNA detection rate of 90%, whereas for conventional karyotyping this was 61%. In addition, many small (<5 Mb) genetic lesions were encountered, frequently harboring clinically relevant ALL‐related genes such as CDKN2A/B, ETV6, PAX5, and IKZF1. From our data we conclude that microarray‐based genomic profiling serves as a robust tool in the genetic diagnosis of ALL, outreaching conventional karyotyping in CNA detection both in terms of sensitivity and specificity. We also propose a practical workflow for a comprehensive and objective interpretation of CNAs obtained through microarray‐based genomic profiling, thereby facilitating its application in a routine clinical diagnostic setting.

Detection of cryptic subtelomeric imbalances in fetuses with ultrasound abnormalities.

It is known from postnatal diagnosis that imbalances of the subtelomeric regions contribute significantly to idiopathic mental retardation. Consequently, subtelomere screening has been incorporated into the recommendations for the evaluation of individuals with unexplained mental retardation and a normal karyotype. Previous studies suggested that for fetuses with ultrasound abnormalities and a normal karyotype, additional screening for submicroscopic imbalances can be relevant for diagnosis and prognosis. In the present paper, we report the detection of such (subtelomeric) imbalances in three fetuses. Prenatally, the three fetuses presented with ultrasound abnormalities highly suspected of a chromosomal aberration. In two of the fetuses, routine karyotyping showed no aberrations but with MLPA or FISH a small subtelomeric imbalance, that could explain the anomalies, was detected. In the third fetus, a chromosomal abnormality was detected with routine cytogenetic analysis (del(X)(p22.1)), but this abnormality could not explain the ultrasound observations and only with subtelomere screening by MLPA a causative chromosomal aberration was detected. As the three fetuses were already prenatally suspected of a chromosomal aberration, this underlines the potential relevance of subtelomere screening in such fetuses, leading to better clinical diagnosis, prognosis and care. Furthermore, when using MLPA, the analysis can be extended to other regions of known clinical importance.

Identification of prognostic relevant chromosomal abnormalities in chronic lymphocytic leukemia using microarray-based genomic profiling

BackgroundCharacteristic genomic abnormalities in patients with B cell chronic lymphocytic leukemia (CLL) have been shown to provide important prognostic information. Fluorescence in situ hybridization (FISH) and multiplex ligation-dependent probe amplification (MLPA), currently used in clinical diagnostics of CLL, are targeted tests aimed at specific genomic loci. Microarray-based genomic profiling is a new high-resolution tool that enables genome-wide analyses. The aim of this study was to compare two recently launched genomic microarray platforms, i.e., the CytoScan HD Array (Affymetrix) and the HumanOmniExpress Array (Illumina), with FISH and MLPA to ascertain whether these latter tests can be replaced by either one of the microarray platforms in a clinical diagnostic setting.ResultMicroarray-based genomic profiling and FISH were performed in all 28 CLL patients. For an unbiased comparison of the performance of both microarray platforms 9 patients were evaluated on both platforms, resulting in the identification of exactly identical genomic aberrations. To evaluate the detection limit of the microarray platforms we included 7 patients in which the genomic abnormalities were present in a relatively low percentage of the cells (range 5-28%) as previously determined by FISH. We found that both microarray platforms allowed the detection of copy number abnormalities present in as few as 16% of the cells. In addition, we found that microarray-based genomic profiling allowed the identification of genomic abnormalities that could not be detected by FISH and/or MLPA, including a focal TP53 loss and copy neutral losses of heterozygosity of chromosome 17p.ConclusionFrom our results we conclude that although the microarray platforms exhibit a somewhat lower limit of detection compared to FISH, they still allow the detection of copy number abnormalities present in as few as 16% of the cells. By applying similar interpretation criteria, the results obtained from both platforms were comparable. In addition, we conclude that both microarray platforms allow the identification of additional potential prognostic relevant abnormalities such as focal TP53 deletions and copy neutral losses of heterozygosity of chromosome 17p, which would have remained undetected by FISH or MLPA. The prognostic relevance of these novel genomic alterations requires further evaluation in prospective clinical trials.

The human gene for water channel aquaporin 1 (AQP1) is localized on chromosome 7p15→p14

The chromosomal localization of the gene encoding aquaporin 1 (previously called CHIP28), which acts as a water channel in erythrocytes and in the renal proximal tubules and descending limbs of Henle, was determined. Southern blot hybridizations on chromosomal DNA of a panel of 25 different human x rodent hybrid cell lines localized the aquaporin 1 gene to human chromosome 7. Additionally, in situ hybridization on R-banded metaphase chromosomes sublocalized the aquaporin 1 gene (AQP1) to 7p15-->p14, and some sequence-tagged sites in this region were identified.