Clinical validation of an array CGH test for HER2 status in breast cancer reveals that polysomy 17 is a rare event.

The HER2 gene is an important prognostic and therapeutic marker in newly diagnosed breast cancer. Currently, HER2 status is most frequently determined by immunohistochemical detection of HER2 protein expression on the cellular membrane surface or by fluorescence in situ hybridization analysis of HER2 gene copy number in fixed tissue using locus-specific probes for the HER2 gene and chromosome 17 centromere. However, these methods are problematic because of issues with intra- and inter-laboratory reproducibility and preanalytic variables, such as fixation time. In addition, the commonly used HER2/chromosome 17 ratio presumes that chromosome 17 polysomy is present when the centromere is amplified, even though analysis of the rest of the chromosome is not included in the assay. In this study, 97 frozen samples of invasive lobular and invasive ductal carcinoma, with known immunohistochemistry and fluorescence in situ hybridization results for HER2, were analyzed by comparative genomic hybridization to a commercially available bacterial artificial chromosome whole-genome array containing 99 probes targeted to chromosome 17 and the HER2/TOP2 amplicon. Results were 97% concordant for HER2 status, meeting the College of American Pathologists/American Society of Clinical Oncology's validation requirements for HER2 testing. Surprisingly, not a single case of complete polysomy 17 was detected even though multiple breast cancer cases showed clear polysomies of other chromosomes. We conclude that array comparative genomic hybridization is an accurate and objective DNA-based alternative for clinical evaluation of HER2 gene copy number, and that polysomy 17 is a rare event in breast cancer.

Array CGH analysis of chronic lymphocytic leukemia reveals frequent cryptic monoallelic and biallelic deletions of chromosome 22q11 that include the PRAME gene.

We used BAC array-based CGH to detect genomic imbalances in 187 CLL cases. Submicroscopic deletions of chromosome 22q11 were observed in 28 cases (15%), and the frequency of these deletions was second only to loss of the 13q14 region, the most common genomic aberration in CLL. Oligonucleotide-based array CGH analysis showed that the 22q11 deletions ranged in size from 0.34 Mb up to approximately 1 Mb. The minimally deleted region included the ZNF280A, ZNF280B, GGTLC2, and PRAME genes. Quantitative real-time PCR revealed that ZNF280A, ZNF280B, and PRAME mRNA expression was significantly lower in the 22q11 deletion cases compared to non-deleted cases.

Whole-genome scanning by array comparative genomic hybridization as a clinical tool for risk assessment in chronic lymphocytic leukemia.

Array-based comparative genomic hybridization (array CGH) provides a powerful method for simultaneous genome-wide scanning and prognostic marker assessment in chronic lymphocytic leukemia (CLL). In the current study, commercially available bacterial artificial chromosome and oligonucleotide array CGH platforms were used to identify chromosomal alterations of prognostic significance in 174 CLL cases. Tumor genomes were initially analyzed by bacterial artificial chromosome array CGH followed by confirmation and breakpoint mapping using oligonucleotide arrays. Genomic changes involving loci currently interrogated by fluorescence in situ hybridization (FISH) panels were detected in 155 cases (89%) at expected frequencies: 13q14 loss (47%), trisomy 12 (13%), 11q loss (11%), 6q loss (7.5%), and 17p loss (4.6%). Genomic instability was the second most commonly identified alteration of prognostic significance with three or more alterations involving loci not interrogated by FISH panels identified in 37 CLL cases (21%). A subset of 48 CLL cases analyzed by six-probe FISH panels (288 total hybridizations) was concordant with array CGH results for 275 hybridizations (95.5%); 13 hybridizations (4.5%) were discordant because of clonal populations that comprised less than 30% of the sample. Array CGH is a powerful, cost-effective tool for genome-wide risk assessment in the clinical evaluation of CLL.

The HemeScan test for genomic prognostic marker assessment in chronic lymphocytic leukemia.

BACKGROUND: Whole-genome analysis by array-based comparative genomic hybridization (array CGH) is an emerging technique for the detection of recurrent unbalanced chromosomal aberrations in chronic lymphocytic leukemia (CLL). These chromosomal changes can be highly predictive of clinical course and are evaluated at present using classical cytogenetics and interphase fluorescence in situ hybridization. However, the significant limitations of these assays have resulted in efforts to move array CGH from use as a discovery tool in the research laboratory into the clinical laboratory as an alternative method for the evaluation of genomic prognostic markers in patients with CLL. OBJECTIVE: The HemeScan(™) array was developed as a clinical tool to provide prognostic marker identification with simultaneous diagnostic monitoring of the entire genome in CLL and other hematological malignancies. METHODS: The authors review representative data from clinical testing of HemeScan for genomic aberration identification in CLL and present suggestions for the integration of array CGH genome scanning into the clinical laboratory. RESULTS/CONCLUSION: The HemeScan assay for CLL precludes the need for G-banded cytognetics by simultaneously revealing prognostic marker status and the level of genomic complexity in > 85% of cases.

Comparative genomic hybridization arrays in clinical pathology: progress and challenges.

Array-based comparative genomic hybridization (array CGH) genome scanning is a powerful method for the global detection of gains and losses of genetic material in both congenital and neoplastic disorders. When used as a clinical diagnostic test, array CGH combines the whole genome perspective of traditional G-banded cytogenetics with the targeted identification of cryptic chromosomal abnormalities characteristic of fluorescence in situ hybridization (FISH). However, the presence of structural variants in the human genome can complicate analysis of patient samples, and array CGH does not provide morphologic information about chromosome structure, balanced translocations, or the actual chromosomal location of segmental duplications. Identification of such anomalies has significant diagnostic and prognostic implications for the patient. We therefore propose that array CGH should be used as a guide to the presence of genomic structural rearrangements in germline and tumor genomes that can then be further characterized by FISH or G-banding, depending on the clinical scenario. In this article, we share some of our experiences with diagnostic array CGH and discuss recent progress and challenges involved with the integration of array CGH into clinical laboratory medicine.

Sequences in antibody molecules important for receptor-mediated transport into the chicken egg yolk.

Large quantities of antibodies are transported into the yolk of the chicken's egg. We have identified several regions within the antibody molecule important for its uptake into the egg yolk. An intact Fc and hinge region but not the Fc-associated carbohydrate are required for transport. Our data suggest that the C(H)2/C(H)3 interface is recognized by the receptor responsible for immunoglobulin (Ig) transport. At this interface, residues 251-254 form an exposed loop on the surface of C(H)2. Chicken IgY (cIgY) has the sequence LYIS and human IgG (hIgG) has the sequence LMIS at these positions; mutation of MIS to glycines results in an IgG that is not transported. A second site important for transport is at positions 429-432 within C(H)3. All transported antibodies have the sequence HEAL, whereas, murine IgG2b (mIgG2b) with the sequence HEGL and cIgA with the sequence HDGI fail to be transported. hIgA has the HEAL sequence and is transported.