Stephanie A. Smoley

Prospective Evaluation of Clonal Evolution During Long-Term Follow-Up of Patients With Untreated Early-Stage Chronic Lymphocytic Leukemia

PURPOSE Retrospective studies suggest cytogenetic abnormalities detected by interphase fluorescent in situ hybridization (FISH) can identify patients with chronic lymphocytic leukemia (CLL) who will experience a more aggressive disease course. Other studies suggest that patients may acquire chromosome abnormalities during the course of their disease. There are minimal prospective data on the clinical utility of the widely used hierarchical FISH prognostic categories in patients with newly diagnosed early-stage CLL or the frequency of clonal evolution as determined by interphase FISH. PATIENTS AND METHODS Between 1994 and 2002, we enrolled 159 patients with previously untreated CLL (83% Rai stage 0/I) on a prospective trial evaluating clonal evolution by FISH. Patients provided baseline and follow-up specimens for FISH testing during 2 to 12 years. RESULTS Chromosomal abnormalities detected by FISH at study entry predicted overall survival. Eighteen patients experienced clonal evolution during follow-up. The rate of clonal evolution increased with duration of follow-up with only one occurrence in the first 2 years (n = 71; 1.4%) but 17 occurrences (n = 63; 27%) among patients tested after 5+ years. Clonal evolution occurred among 10% of ZAP-70-negative and 42% of ZAP-70-positive patients at 5+ years (P = .008). CONCLUSION This clinical trial confirms prospectively that cytogenetic abnormalities detected by FISH can predict overall survival for CLL patients at the time of diagnosis, but also suggests that many patients acquire new abnormalities during the course of their disease. Patients with higher ZAP-70 expression may be more likely to experience such clonal evolution. These findings have important implications for both clinical management and trials of early treatment for patients with high-risk, early-stage CLL.

A comprehensive evaluation of the prognostic significance of 13q deletions in patients with B‐chronic lymphocytic leukaemia

Deletion 13q14 on fluorescence in situ hybridization (FISH) analysis is the most common cytogenetic abnormality in chronic lymphocytic leukaemia (CLL), and is a favourable prognostic biomarker when detected as a sole abnormality. We intensively interrogated clinical outcome in 323 consecutive, untreated CLL patients with isolated 13q‐ identified within 2 years of diagnosis. We also analyzed outcome in 217 additional patients with deletion 11q22.3 or 17p13.1, or trisomy 12, based on whether these occurred in isolation or in conjunction with 13q‐. Patients with a heterozygous 13q‐ and those with a homozygous deletion had similar time to first treatment (TFT) and overall survival (OS). In contrast, a higher percentage of 13q‐ nuclei was associated with significantly shorter TFT (P < 0·001). The 5‐year untreated rate was 79% for patients with isolated 13q‐ in ≤65·5% of nuclei compared to 38% among those with 13q‐ in >65·5% of nuclei (P < 0·001). The percentage of nuclei exhibiting 13q‐ remained an independent predictor of TFT after controlling for ZAP‐70, IGHV, or CD38 (all P < 0·001). Among patients with 13q‐ plus one other FISH abnormality, concomitant 13q‐ appeared to attenuate the shorter survival associated with 17p‐ (P = 0·019). The clinical implications of 13q‐ in CLL appear more complex than originally appreciated.

Interphase fluorescence in situ hybridization with an IGH probe is important in the evaluation of patients with a clinical diagnosis of chronic lymphocytic leukaemia

Translocations involving IGH are common in some lymphoid malignancies but are believed to be rare in chronic lymphocytic leukaemia (CLL). To study the clinical utility of fluorescence in situ hybridization (FISH) for IGH translocations, we reviewed 1032 patients with a presumptive diagnosis of CLL. Seventy‐six (7%) patients had IGH translocations. Pathology and clinical data were available for the 24 patients evaluated at the Mayo Clinic. Ten (42%) patients had IGH/cyclin D1 fusion and were diagnosed with mantle cell lymphoma (MCL). The immunophenotype was typical of MCL in three of these patients and atypical for MCL in seven patients. One patient had biclonal disease with typical MCL and CLL with IGH/BCL‐2. Eleven (46%) patients had IGH/BCL‐2 fusion including the patient with biclonal disease. Two of these patients had leukaemic phase follicular lymphoma and nine patients had CLL. The median progression‐free survival of patients with CLL and IGH/BCL‐2 translocation was 20·6 months. The two patients with IGH/BCL‐3 fusion (one of these also had IGH/BCL‐11a) had rapid disease progression. The IGH partner gene was not identified in two patients. We conclude that use of an IGH probe in FISH analysis of monoclonal B‐cell lymphocytosis improves diagnostic precision and could have prognostic value in patients with CLL.

Stimulation of chronic lymphocytic leukemia cells with CpG oligodeoxynucleotide gives consistent karyotypic results among laboratories: a CLL Research Consortium (CRC) Study

Cytogenetic abnormalities are important prognostic indicators in CLL. Historically, only interphase cytogenetics was clinically useful in CLL, because traditional mitogens are not effective mitotic stimulants. Recently, CpG-oligodeoxynucleotide (ODN) stimulation has shown effectiveness in CLL cells. The CLL Research Consortium tested the effectiveness and reproducibility of CpG-ODN stimulation for detecting chromosomally abnormal clones by five laboratories. More clonal abnormalities were observed after culture of CLL cells with CpG-ODN than with the traditional pokeweed mitogen plus 12-O-tetradecanoylphorbol-13-acetate (PWM+TPA). All clonal abnormalities in PWM+TPA cultures were observed in CpG-ODN cultures, whereas CpG-ODN identified some clones not found by PWM+TPA. CpG-ODN stimulation of one normal control sample and 12 CLL samples showed that, excepting clones of del(13q) in low frequencies and one translocation, results in all five laboratories were consistent, and all abnormalities were concordant with FISH. Abnormal clones in CLL were more readily detected with CpG-ODN stimulation than with traditional B-cell mitogens. With CpG-ODN stimulation, abnormalities were reproducible among cytogenetic laboratories. CpG-ODN did not appear to induce aberrations in cell culture, but did enhance detection of abnormalities and complexity in CLL. Because karyotypic complexity is prognostic and is not detectable by standard FISH analyses, stimulation with CpG-ODN is useful for identifying this additional prognostic factor in CLL.

Longitudinal genome-wide analysis of patients with chronic lymphocytic leukemia reveals complex evolution of clonal architecture at disease progression and at the time of relapse

Longitudinal genome-wide analysis of patients with chronic lymphocytic leukemia reveals complex evolution of clonal architecture at disease progression and at the time of relapse

Patients with chronic lymphocytic leukaemia and clonal deletion of both 17p13.1 and 11q22.3 have a very poor prognosis

Detection of a 17p13.1 deletion (loss of TP53) or 11q22.3 deletion (loss of ATM), by fluorescence in situ hybridization (FISH), in chronic lymphocytic leukaemia (CLL) patients is associated with a poorer prognosis. Because TP53 and ATM are integral to the TP53 pathway, we hypothesized that 17p13.1‐ (17p‐) and 11q22.3‐ (11q‐) occurring in the same cell (clonal 17p‐/11q‐) would confer a worse prognosis than either 17p‐ or 11q‐. We studied 2184 CLL patients with FISH (1995–2012) for the first occurrence of 17p‐, 11q‐, or clonal 17p‐/11q‐. Twenty (1%) patients had clonal 17p–/11q‐, 158 (7%) had 17p‐ (including 4 with 17p‐ and 11q‐ in separate clones), 247 (11%) had 11q‐, and 1759 (81%) had neither 17p‐ nor 11q‐. Eleven of 15 (73%) tested patients with clonal 17p‐/11q‐ had dysfunctional TP53 mutations. Overall survival for clonal 17p‐/11q‐ was significantly shorter (1·9 years) than 17p‐ (3·1 years, P = 0·04), 11q‐ (4·8 years, P ≤ 0·0001), or neither 17p‐ nor 11q‐ (9·3 years, P ≤ 0·0001). Clonal 17p‐/11q‐ thus conferred significantly worse prognosis, suggesting that loss of at least one copy of both TP53 and ATM causes more aggressive disease. Use of an ATM/TP53 combination FISH probe set could identify these very‐high risk patients.

A novel tricolor, dual-fusion fluorescence in situ hybridization method to detect BCR/ABL fusion in cells with t(9;22)(q34;q11.2) associated with deletion of DNA on the derivative chromosome 9 in chronic myelocytic leukemia.

Dual-color, dual-fusion fluorescence in situ hybridization (D-FISH) can accurately detect and quantify cells with BCR/ABL fusion in <1% of 500 nuclei in 80% of patients with chronic myelocytic leukemia (CML) and t(9;22)(q34;q11.2). The remaining patients have one of three forms of atypical D-FISH patterns; these patterns have different sensitivities to detect disease. Neoplastic cells with one ABL, one BCR, and one BCR/ABL fusion are particularly problematic, because normal cells with coincidental overlap have the same pattern. For these patients, the normal cutoff for D-FISH is >23%. We tested a new method that incorporates an aqua-labeled probe for the argininosuccinate synthetase (ASS) gene into the conventional BCR/ABL D-FISH probe set. This tricolor D-FISH (TD-FISH) method takes advantage of the aqua-labeled ASS probe to distinguish between neoplastic and normal cells. We used TD-FISH to study 20 normal specimens and 35 specimens from 20 patients with known loss of both BCR and ABL from the derivative chromosome 9. The results show that TD-FISH effectively discriminates between cells with overlapping BCR and ABL signals from cells with true BCR/ABL fusion and improves the ability to quantify minimal residual disease from >23% to >1% of 500 interphase nuclei.

Fluorescence In Situ Hybridization to Visualize Genetic Abnormalities in Interphase Cells of Acinar Cell Carcinoma, Ductal Adenocarcinoma, and Islet Cell Carcinoma of the Pancreas

OBJECTIVE To use fluorescence in situ hybridization (FISH) to visualize genetic abnormalities in interphase cell nuclei (interphase FISH) of acinar cell carcinoma, ductal adenocarcinoma, and islet cell carcinoma of the pancreas. PATIENTS AND METHODS Between April 4, 2007, and December 4, 2008, interphase FISH was used to study paraffin-embedded preparations of tissue obtained from 18 patients listed in the Mayo Clinic Biospecimen Resource for Pancreas Research with a confirmed diagnosis of acinar cell carcinoma, ductal adenocarcinoma, islet cell carcinoma, or pancreas without evidence of neoplasia. FISH probes were used for chromosome loci of APC (see glossary at end of article for expansion of all gene symbols), BRCA2, CTNNB1, EGFR, ERBB2, CDKN2A, TP53, TYMP, and TYMS . These FISH probes were used with control probes to distinguish among various kinds of chromosome abnormalities of number and structure. RESULTS FISH abnormalities were observed in 12 (80%) of 15 patients with pancreatic cancer: 5 of 5 patients with acinar cell carcinoma, 5 of 5 patients with ductal adenocarcinoma, and 2 (40%) of 5 patients with islet cell carcinoma. All 3 specimens of pancreatic tissue without neoplasia had normal FISH results. Gains of CTNNB1 due to trisomy 3 occurred in each tumor with acinar cell carcinoma but in none of the other tumors in this study. FISH abnormalities of all other cancer genes studied were observed in all forms of pancreatic tumors in this investigation. CONCLUSION FISH abnormalities of CTNNB1 due to trisomy 3 were observed only in acinar cell carcinoma. FISH abnormalities of genes implicated in familial cancer, tumor progression, and the 5-fluorouracil pathway were common but were not associated with specific types of pancreatic cancer.

Standardization of fluorescence in situ hybridization studies on chronic lymphocytic leukemia (CLL) blood and marrow cells by the CLL Research Consortium

Five laboratories in the Chronic Lymphocytic Leukemia (CLL) Research Consortium (CRC) investigated standardizing and pooling of fluorescence in situ hybridization (FISH) results as a collaborative research project. This investigation used fixed bone marrow and blood cells available from previous conventional cytogenetic or FISH studies in two pilot studies, a one-day workshop, and proficiency test. Multiple FISH probe strategies were used to detect 6q-, 11q-, +12, 13q-, 17p-, and IGH rearrangements. Ten specimens were studied by participants who used their own probes (pilot study 1). Of 312 FISH interpretations, 224 (72%) were true-negative, 74 (24%) true-positive, 6 (2%) false-negative, and 8 (3%) false-positive. In pilot study no. 2, each participant studied two specimens using identical FISH probe sets to control for variation due to probe sets and probe strategies. Of 80 FISH interpretations, no false interpretations were identified. At a subsequent workshop, discussions produced agreement on scoring criteria. The proficiency test that followed produced no false-negative results and 4% (3/68) false-positive interpretations. Interpretation disagreements among laboratories were primarily attributable to inadequate normal cutoffs, inconsistent scoring criteria, and the use of different FISH probe strategies. Collaborative organizations that use pooled FISH results may wish to impose more conservative empiric normal cutoff values or use an equivocal range between the normal cutoff and the abnormal reference range to eliminate false-positive interpretations. False-negative results will still occur, and would be expected in low-percentage positive cases; these would likely have less clinical significance than false positive results. Individual laboratories can help by closely following rigorous quality assurance guidelines to ensure accurate and consistent FISH studies in their clinical practice and research.

Validation of a new three-color fluorescence in situ hybridization (FISH) method to detect CHIC2 deletion, FIP1L1/PDGFRA fusion and PDGFRA translocations

The PDGRFA locus has become a gene of interest based on mutational activation in various myeloid neoplasms and the availability of targeted therapies (i.e., imatinib mesylate) to its overexpression. We studied a new FISH method to detect CHIC2 deletion, FIP1L1/PDGFRA fusion and PDGFRA translocation in patients with myeloid neoplasms associated with eosinophilia. A total of 46 specimens were studied, including 15 from patients with a CHIC2 abnormality and six patients with an abnormality involving PDGFRA. Our results revealed this new FISH assay accurately detects these abnormalities and will be a useful clinical test for patients with myeloid neoplasms and eosinophilia.