Liquid bead array technology in the detection of common translocations in acute and chronic leukemias.

Hematologic malignancies often have specific chromosomal translocations that promote cancer initiation and progression. Translocation identification is often vital in the diagnosis, prognosis, and treatment of malignancies. A variety of methods including metaphase cytogenetics, in situ hybridization, microarray techniques, Southern blotting, and many variations of PCR are used to identify translocations. While all these techniques have utility, many have drawbacks limiting their clinical usefulness: high cost, slow turnaround time, low density, large sample requirements, high complexity, and difficult validation and standardization. Multiplexed RT-PCR combined with liquid bead array detection overcomes many of these limitations, allowing simultaneous amplification and detection of multiple translocations within one patient sample. This system has high reliability, reproducibility, and flexibility; low cost and low complexity; rapid turnaround time; and appropriate analyte density. Recently, Asuragen Inc. has developed a multiplexed RT-PCR liquid bead array panel that simultaneously analyzes 12 fusion transcripts found in four major types of hematologic malignancies, allowing rapid and efficient diagnosis. In this chapter, we review liquid bead array technology in relation to the specific hematologic translocations analyzed in the Signature LTx panel.

Analysis of hematopoietic stem cell transplant engraftment: use of loss or gain of microsatellite alleles to identify residual hematopoietic malignancy.

Polymorphic short tandem repeat (STR), or microsatellite, loci have been widely used to analyze chimerism status after allogeneic hematopoietic stem cell transplantation. The presence of a patient's DNA, as identified by STR analysis, may indicate residual or recurrent malignant disease or may represent normal hematopoiesis of patient origin. The ratio of patient-derived to donor-derived alleles is used to calculate the relative amount of patient cells (both benign and malignant) to donor cells. STRs on chromosomes known to be gained or lost in a patient's tumor are generally ignored because it is difficult to perform meaningful calculations of mixed chimerism. However, in this study, we present evidence that STR loci on gained or lost chromosomes are useful in distinguishing the benign or malignant nature of chimeric DNA. In the peripheral blood or bone marrow of 4 hematopoietic stem cell transplantation patients with leukemia or lymphoma, we identified tumor DNA on the basis of STR loci showing copy number alteration. We propose that a targeted evaluation of STR loci showing altered copy number in posttransplant chimerism analysis can provide evidence of residual cancer cells.

Genetic variation in DNA-repair pathways and response to radiochemotherapy in esophageal adenocarcinoma: a retrospective cohort study of the Eastern Cooperative Oncology Group.

BACKGROUND: Recent data in esophageal cancer suggests the variant allele of a single-nucleotide polymorphism (SNP) in XRCC1 may be associated with resistance to radiochemotherapy. However, this SNP has not been assessed in a histologically homogeneous clinical trial cohort that has been treated with a uniform approach. In addition, whether germline DNA may serve as a surrogate for tumor genotype at this locus is unknown in this disease. Our objective was to assess this SNP in relation to the pathologic complete response (pCR) rate in subjects with esophageal adenocarcinoma who received cisplatin-based preoperative radiochemotherapy in a multicenter clinical trial (Eastern Cooperative Oncology Group 1201). As a secondary aim, we investigated the rate of allelic imbalance between germline and tumor DNA. METHODS: Eighty-one eligible treatment-naïve subjects with newly diagnosed resectable esophageal adenocarcinoma received radiotherapy (45 Gy) concurrent with cisplatin-based chemotherapy, with planned subsequent surgical resection. The primary endpoint was pCR, defined as complete absence of tumor in the surgical specimen after radiochemotherapy. Using germline DNA from 60 subjects, we examined the base-excision repair SNP, XRCC1 Arg399Gln, and 4 other SNPs in nucleotide excision (XPD Lys751Gln and Asp312Asn, ERCC1 3' flank) and double-stranded break (XRCC2 5' flank) repair pathways, and correlated genotype with pCR rate. Paired tumor tissue was used to estimate the frequency of allelic imbalance at the XRCC1 SNP. RESULTS: The variant allele of the XRCC1 SNP (399Gln) was detected in 52% of subjects. Only 6% of subjects with the variant allele experienced a pCR, compared to 28% of subjects without the variant allele (odds ratio 5.37 for failing to achieve pCR, p = 0.062). Allelic imbalance at this locus was found in only 10% of informative subjects, suggesting that germline genotype may reflect tumor genotype at this locus. No significant association with pCR was noted for other SNPs. CONCLUSIONS: Assessed for the first time in a prospective, interventional trial cohort of esophageal adenocarcinoma, XRCC1 399Gln was associated with resistance to radiochemotherapy. Further investigation of this genetic variation is warranted in larger cohorts. In addition, these data indicate that germline genotype may serve as a surrogate for tumor genotype at this locus.

Δ-PCR, A Simple Method to Detect Translocations and Insertion/Deletion Mutations.

PCR detection of chromosomal translocations and small insertion/deletion mutations is challenging when potential amplicon size varies greatly. Molecular diagnostic laboratories face such difficulties with the BCL2-IGH translocation in follicular lymphoma and with internal tandem duplication mutation of the FLT3 gene in leukemia, where breakpoints are widely distributed, mutations may be multiple, signal strength is low, and background noise is elevated. We developed a strategy, called Δ-PCR, that ensures PCR specificity and identifies individual breakpoints. Δ-PCR uses two forward primers (external and internal) and a reverse primer simultaneously. The internal primer functions as a probe with a defined distance Δ from the external primer. For follicular lymphoma, we prepared upstream, BCL2-specific primers for potential breakpoints to pair with a common, downstream VLJH primer. Multiplexed PCR amplicons are sized by capillary electrophoresis. Each of the upstream pairs has a defined interval separating them that uniquely identifies the breakpoint. The presence of two amplicons with a defined size difference confirms validity of the rearrangement and identity of the specific breakpoint, even if signal strength is low. By testing 40 follicular lymphoma and 12 control specimens from formalin-fixed, paraffin-embedded (FFPE) blocks, we showed that multiplex Δ-PCR is a simple, sensitive strategy to identify translocations with multiple breakpoints or partners. The strategy was also applied to detect minor leukemic clones with internal tandem duplication mutations and could have broader applications for other insertion/deletion and duplication mutations.

Comparison of Sanger sequencing, pyrosequencing, and melting curve analysis for the detection of KRAS mutations: diagnostic and clinical implications.

Mutations in codons 12 and 13 of the KRAS oncogene are relatively common in colorectal and lung adenocarcinomas. Recent data indicate that these mutations result in resistance to anti-epidermal growth factor receptor therapy. Therefore, we assessed Sanger sequencing, pyrosequencing, and melting curve analysis for the detection of KRAS codon 12/13 mutations in formalin-fixed paraffin-embedded samples, including 58 primary and 42 metastatic colorectal adenocarcinomas, 63 primary and 17 metastatic lung adenocarcinomas, and 20 normal colon samples. Of 180 tumor samples, 62.2% were KRAS mutant positive, and 37.8% were negative. Melting curve analysis yielded no false positive or false negative results, but had 10% equivocal calls. Melting curve analysis also resulted in 4 cases with melting curves inconsistent with either wild-type or codon 12/13 mutations. These patterns were generated from samples with double mutants in codons 12/13 and with mutations outside of codons 12/13. Pyrosequencing yielded no false positive or false negative results as well. However, two samples from one patient yielded a pyrogram that was flagged as abnormal, but the mutation subtype could not be determined. Finally, using an electronic cutoff of 10%, Sanger sequencing showed 11.1% false positives and 6.1% false negatives. In our hands, the limit of detection for Sanger sequencing, pyrosequencing, and melting curve analysis was approximately 15 to 20%, 5%, and 10% mutant alleles, respectively.

Lack of a y-chromosomal complement in the majority of gestational trophoblastic neoplasms.

Gestational trophoblastic neoplasms (GTNs) are a rare group of neoplastic diseases composed of choriocarcinomas, placental site trophoblastic tumors (PSTTs) and epithelioid trophoblastic tumors (ETTs). Since these tumors are derivatives of fetal trophoblastic tissue, approximately 50% of GTN cases are expected to originate from a male conceptus and carry a Y-chromosomal complement according to a balanced sex ratio. To investigate this hypothesis, we carried out a comprehensive analysis by genotyping a relatively large sample size of 51 GTN cases using three independent sex chromosome genetic markers; Amelogenin, Protein Kinase and Zinc Finger have X and Y homologues that are distinguishable by their PCR product size. We found that all cases contained the X-chromosomal complement while only five (10%) of 51 tumors harbored the Y-chromosomal complement. Specifically, Y-chromosomal signals were detected in one (5%) of 19 choriocarcinomas, one (7%) of 15 PSTTs and three (18%) of 17 ETTs. The histopathological features of those with a Y-chromosome were similar to those without. Our results demonstrate the presence of a Y-chromosomal complement in GTNs, albeit a low 10% of cases. This shortfall of Y-chromosomal complements in GTNs may reinforce the notion that the majority of GTNs are derived from previous molar gestations.

Molecular genotyping of hydatidiform moles: analytic validation of a multiplex short tandem repeat assay.

Distinction of hydatidiform moles from non-molar (NM) specimens, as well as their subclassification as complete (CHM) versus partial hydatidiform moles (PHM), is important for clinical management and accurate risk assessment for persistent gestational trophoblastic disease. Because diagnosis of hydatidiform moles based solely on morphology suffers from poor interobserver reproducibility, a variety of ancillary techniques have been developed to improve diagnosis. Immunohistochemical assessment of the paternally imprinted, maternally expressed p57 gene can identify CHMs (androgenetic diploidy) by their lack of p57 expression, but cannot distinguish PHMs (diandric monogynic triploidy) from NMs (biparental diploidy). Short tandem repeat genotyping can identify the parental source of polymorphic alleles and thus discern androgenetic diploidy, diandric triploidy, and biparental diploidy, which allows for specific diagnosis of CHMs, PHMs, and NMs, respectively. In this study, a retrospectively collected set of morphologically typical CHMs (n = 8), PHMs (n = 10), and NMs (n = 12) was subjected to an analytic validation study of both short tandem repeat genotyping and p57 immunohistochemistry. Several technical and biological problems resulted in data that were difficult to interpret. To avoid these pitfalls, we have developed an algorithm with quantitative guidelines for the interpretation of short tandem repeat genotyping data.

Application of traditional clinical pathology quality control techniques to molecular pathology.

Many molecular diagnostic laboratories have evolved from research laboratories, initially performing low numbers of homebrew assays, but many laboratories now perform more kit-based assays, with ever increasing test volumes. One such assay is assessment of bone marrow transplantation engraftment. Allogeneic bone marrow transplantation is performed primarily in the treatment of hematological malignancies. Monitoring of engraftment was traditionally evaluated using minisatellites (variable number tandem repeats) and Southern blotting, but most laboratories now use Food and Drug Administration-cleared microsatellite (short tandem repeats) kits to assess the extent of engraftment. With the increase in equipment reliability, the use of kit-based assays, and the desire to provide the highest quality clinical data, we began applying traditional clinical pathology quality control tools to the molecular diagnostics laboratory. In this study, we demonstrate this approach using a microsatellite-based bone marrow engraftment assay. We analyzed control samples (pure and mixed) for two different microsatellites to establish quality control parameters and constructed Levey-Jennings charts to monitor both the precision and accuracy of this assay. By incorporating these tools into an overall quality assurance program, a laboratory can identify systematic errors and perform corrective actions before actual assay failure, thereby improving the quality of patient care.

A molecular fraction collecting tool for the ABI 310 automated sequencer.

Several methods exist to retrieve and purify DNA fragments after agarose or polyacrylamide gel electrophoresis for subsequent analyses. However, molecules present in low concentration and molecules similar in size to their neighbors are difficult to purify. Capillary electrophoresis has become popular in molecular diagnostic laboratories because of its automation, excellent resolution, and high sensitivity. In the current study, the ABI Prism 310 Genetic Analyzer was reconfigured into a fraction collector by adapting the standard gel block to accommodate a collection tube at the distal end of capillary. The time to collect the desired peaks was estimated by extrapolating from standard capillary electrophoresis using the original gel block. Fraction collection from a mixture of DNA fragments amplified from wild type and several internal tandem duplication mutations of the FMS-like tyrosine kinase 3 (Flt3) gene yielded highly purified DNA fragments containing internal tandem duplication mutations and predictable electrokinetics using the reconstructed gel block. The reconfigured instrument could successfully isolate DNA amplicons from extremely low-amplitude peaks (110 relative fluorescent units), which were undetectable using polyacrylamide gel electrophoresis. In addition, we successfully isolated bands that were only three bases apart that comigrated on polyacrylamide gel electrophoresis. DNA sequencing was used to confirm that the correct peaks were recovered at sufficient purity.

Comparison of the microsatellite instability analysis system and the Bethesda panel for the determination of microsatellite instability in colorectal cancers.

Microsatellite instability (MSI) analysis of colorectal cancers is clinically useful to identify patients with hereditary nonpolyposis colorectal cancer (HNPCC) caused by germline mutations of mismatch repair genes. MSI status may also predict cancer response/resistance to certain chemotherapies. We evaluated the MSI Analysis System (Promega Corp.; five mononucleotide and two pentanucleotide repeats) and compared the results to the Bethesda panel, which interrogates five microsatellite loci recommended by the 1997 National Cancer Institute-sponsored MSI workshop (three dinucleotide and two mononucleotide repeats). Thirty-four colorectal cancers were analyzed by both assays. The overall concordance between the two assays was 85% (29 of 34). There was complete concordance between the two assays for all of the MSI-high (11 of 11) and microsatellite stable (MSS; 18 of 18) cases. In the 11 MSI-high cases, all 5 of the mononucleotide loci in the MSI Analysis System demonstrated shifted alleles (100% sensitivity), and each shift resulted in products that were smaller in size than the germline alleles. All (5 of 5) of the cases interpreted as MSI-low by the Bethesda assay were interpreted as MSS by the MSI Analysis System. Our results suggest that the MSI Analysis System is generally superior and may help resolve cases of MSI-low into either MSI-high or MSS.

Bone marrow engraftment analysis after granulocyte transfusion.

We present the case of a 6-year-old male who received an allogeneic bone marrow transplant as part of treatment for acute lymphoblastic leukemia. The patient relapsed 5 months after transplantation and received additional chemotherapy. He acquired an angioinvasive fungal infection that required transfusion of granulocytes. Approximately 5 weeks after relapsing (181 days after transplant), a bone marrow specimen was taken for molecular engraftment analysis and flow cytometry to assess graft loss as well as residual disease. The engraftment results generated by the multiple short tandem repeat loci tested were inconsistent, and alleles were present at several loci that were of neither patient nor donor origin. An error in specimen identification was initially considered. Further investigation into the circumstances surrounding procurement of the patient's bone marrow aspirate revealed that the patient had received a granulocyte transfusion approximately 10 hours before the bone marrow specimen was taken. In addition, morphological and flow cytometric analyses of the same bone marrow aspirate demonstrated a significant degree of peripheral blood contamination. We determined that the unknown alleles in the bone marrow engraftment specimen were derived from the donor of the transfused granulocytes. This case illustrates that white cell transfusion can lead to erroneous bone marrow engraftment results, particularly if only one microsatellite locus is used to monitor engraftment.

A single nucleotide primer extension assay to detect the APC I1307K gene variant.

Adenomatous polyposis coli (APC) is a tumor suppressor gene important in colorectal tumorigenesis. A genetic variant of APC, I1307K, results from a T-to-A transversion at nucleotide 3920 which converts the wild-type sequence to a homopolymer tract (A(8)). The I1307K alteration is not itself oncogenic, but creates a hypermutable region (A(8)) that is prone to frame-shift mutations. The APC I1307K variant occurs in approximately 6% of the Ashkenazi Jewish population and is reported to approximately double an individual's risk for colorectal cancer. Here we describe a single nucleotide primer extension assay for the detection of the APC I1307K mutation. Following PCR amplification, nucleotide 3920 of the APC gene is directly sequenced using single nucleotide primer extension technology. The assay is in a multiplex format allowing simultaneous forward and reverse sequencing of the I1307K variant, which provides an internal, independent confirmation of each testing result. The assay was validated against 60 samples previously characterized by an allele-specific oligonucleotide (ASO) hybridization assay, with 100% concordance of results. Compared to the ASO assay, this single nucleotide primer extension assay requires significantly less technical time to perform, and has a greatly increased throughput capacity. The single nucleotide extension assay provides a highly sensitive and specific assay to identify individuals with the APC I1307K gene variant who may benefit from increased colorectal screening.

Detection of FLT3 internal tandem duplication and D835 mutations by a multiplex polymerase chain reaction and capillary electrophoresis assay.

FLT3 is a receptor tyrosine kinase that is expressed on early hematopoietic progenitor cells and plays an important role in stem cell survival and differentiation. Two different types of functionally important FLT3 mutations have been identified. Internal tandem duplication mutations arise from duplications of the juxtamembrane portion of the gene and result in constitutive activation of the FLT3 protein. This alteration has been identified in approximately 20% to 30% of patients with acute myelogenous leukemia and appears to be associated with a worse prognosis. The second type of FLT3 mutation, missense mutations at aspartic acid residue 835, occurs in approximately 7.0% of acute myelogenous leukemia cases. These mutations also appear to be activating and to portend a worse prognosis. Identification of FLT3 mutations is important because it provides prognostic information and may play a pivotal role in determining appropriate treatment options. We have developed an assay to identify both internal tandem duplication and D835 FLT3 mutations in a single multiplex polymerase chain reaction. After amplification, the polymerase chain reaction products are analyzed by capillary electrophoresis for length mutations and resistance to EcoRV digestion. Here we describe the performance characteristics of the assay, assay validation, and our clinical experience using this assay to analyze 147 clinical specimens.