Sandra Elmore

Epstein-Barr Virus (EBV) DNA in plasma is not encapsidated in patients with EBV-related malignancies.

Epstein-Barr Virus (EBV), a ubiquitous gamma herpes virus, infects more than 95% of the human population before adulthood. Life-long persistence, usually without adverse health consequences, relies on a balance between viral latency, viral replication, and host immune response. Patients with EBV-related disease often have high levels of EBV DNA in their plasma. This study addresses whether this circulating, cell-free EBV DNA is encapsidated in virions or exists as naked genomes. First, an assay was developed, combining DNase I and quantitative real-time PCR, to discriminate encapsidated from naked EBV DNA. EBV DNA was almost always naked in the plasma of AIDS-related lymphoma patients (n = 11) and immunosuppressed/posttransplantation patients (n = 8). In contrast, infectious mononucleosis patients (n = 30) often had a mixture of encapsidated and naked EBV DNA. These findings may be important in understanding how viral load relates to disease status and in predicting response to nucleoside analogs and other antiviral therapies.

High Levels of Epstein-Barr Virus DNA in Latently Infected Gastric Adenocarcinoma

Gastric adenocarcinoma is the second leading cause of cancer death worldwide. Epstein–Barr virus (EBV) is present in the malignant cells of approximately 10% of cases. It is unclear whether EBV is being missed in some gastric adenocarcinomas due to insensitive test methods or partial EBV genome loss. In this study, we screened 113 gastric adenocarcinomas from low- and high-incidence regions (United States and Central America) for the presence of EBV using a battery quantitative real-time PCR (Q-PCR) assays targeting disparate segments of the EBV genome (BamH1W, EBNA1, LMP1, LMP2, BZLF1, EBER1) and histochemical stains targeting EBV-encoded RNA (EBER), the latent proteins LMP1 and LMP2, and the lytic proteins BMRF1 and BZLF1. EBV DNA was detected by Q-PCR in 48/75 United States cancers (64%) and in 38/38 Central American cancers (100%), which was a significant differrence. EBER was localized to malignant epithelial cells in 8/48 (17%) United States and 3/38 (8%) Central American cancers. Viral loads were considerably higher for EBER-positive vs EBER-negative cancers (mean 162 986 vs 62 EBV DNA copies per 100 000 cells). A viral load of 2000 copies per 100 000 cells is recommended as the threshold distinguishing EBER-positive from EBER-negative tumors. One infected cancer selectively failed to amplify the LMP2 gene because of a point mutation, whereas another cancer had an atypical pattern of Q-PCR positivity suggesting deletion of large segments of the EBV genome. Three different viral latency profiles were observed in the cancers based on constant expression of EBER and focal or variable expression of LMP1 or LMP2, without lytic protein expression. We conclude that EBV DNA levels generally reflect EBER status, and a panel of at least two Q-PCR assays is recommended for sensitive identification of infected cancers.

Distribution of Epstein‐Barr viral load in serum of individuals from nasopharyngeal carcinoma high‐risk families in Taiwan

The utility of EBV load as a tumor marker in nasopharyngeal carcinoma (NPC) patients suggests that it might also serve as a screening test for individuals who are at high risk for developing NPC. We previously demonstrated that unaffected individuals from high‐risk families had elevated anti‐EBV antibody levels compared to community controls. In this study, we measured EBV load using 2 different real‐time PCR assays (targeting BamH1W and polymerase gene sequences, respectively) carried out in 2 independent research labs in serum samples from 19 untreated NPC cases, 11 healthy community controls and 100 unaffected individuals from families in which 2 or more individuals were affected with NPC. EBV genomes were detectable in 68% of NPC cases by the EBV BamH1W assay and in 74% by the EBV polymerase assay (κ = 0.64). Patients with stage III or IV disease had significantly higher EBV load compared to those with stage I or II disease (p = 0.008). EBV DNA was detected in a single community control sample by the EBV BamH1W assay and in none of the samples by the EBV polymerase assay. Only one of 100 unaffected family members tested positive by both assays. An additional 14 were positive by only one of the 2 EBV load assays used and usually in only one of the duplicate wells tested, all with very low viral loads (3–50 copies/ml). In addition, EBV load did not correlate with EBV serology results (anti‐VCA, anti‐DNase, anti‐EBNA‐1) among these unaffected family members. In conclusion, our study suggests limited clinical utility of the EBV load test, in its current configuration, to screen individuals from high‐risk families. Should a more sensitive or specific molecular assay be developed that is capable of detecting and distinguishing tumor‐derived EBV genomes or gene products from true negatives, it could be evaluated as a possible screening tool for asymptomatic and early‐stage NPC.

Characteristics of magnetic resonance imaging biomarkers in a natural history study of golden retriever muscular dystrophy

The goal of this study was to assess whether magnetic resonance imaging (MRI) biomarkers can quantify disease progression in golden retriever muscular dystrophy (GRMD) via a natural history study. The proximal pelvic limbs of ten GRMD and eight normal dogs were scanned at 3, 6, and 9-12 months of age. Several MRI imaging and texture analysis biomarkers were quantified in seven muscles. Almost all MRI biomarkers readily distinguished GRMD from control dogs; however, only selected biomarkers tracked with longitudinal disease progression. The biomarkers that performed best were full-length muscle volume and a texture analysis biomarker, termed heterogeneity index. The biceps femoris, semitendinosus and cranial sartorius muscles showed differential progression in GRMD versus control dogs. MRI features in GRMD dogs showed dynamic progression that was most pronounced over the 3- to 6-month period. Volumetric biomarkers and water map values correlated with histopathological features of necrosis/regeneration at 6-months. In conclusion, selected MRI biomarkers (volume and heterogeneity index) in particular muscles (biceps femoris, semitendinosus, and cranial sartorius) adjusted for age effect allow distinction of differential longitudinal progression in GRMD dogs. These biomarkers may be used as surrogate outcome measures in preclinical GRMD trials.

Real-time PCR measures Epstein-Barr Virus DNA in archival breast adenocarcinomas.

The role of Epstein-Barr Virus (EBV) in breast cancer pathogenesis remains controversial. Fifty-five cases of paraffin-embedded, formalin-fixed invasive breast cancer were screened for the presence of EBV using quantitative polymerase chain reaction (PCR) directed at five different targets within the EBV genome (BamH1W, LMP1, EBNA1, LMP2, and BZLF1 regions). In four tumors (7%), low level EBV DNA was detected by at least one of the assays, with levels of up to 11 copies of EBV DNA per 100,000 cells. Immunohistochemisty for viral BMRF1 and BZLF1 and in situ hybridization for lytic gene transcripts showed no evidence of replicative EBV gene expression. Lymphocytes and malignant cells were also negative for latent infection by EBER in situ hybridization. Laser capture microdissection followed by quantitative real-time PCR was not useful in localizing EBV DNA to malignant cells or bystander lymphocytes. In conclusion, EBV DNA is detectable in a fraction of breast cancer specimens using real-time PCR as a screening tool, albeit at quite low levels, which suggests that only rare cells are infected. The low levels probably confounded our ability to localize the virus to particular cell types or to characterize viral gene expression.

Cytomegalovirus DNA measurement in blood and plasma using Roche LightCycler CMV quantification reagents.

Cytomegalovirus (CMV) is a common cause of morbidity and mortality in immunosuppressed patients. Newly available commercial systems facilitate the measurement of CMV DNA in whole blood or plasma, as a means of detecting and monitoring active disease. We evaluated the performance characteristics of a quantitative polymerase chain reaction that relies on analyte-specific reagents and instruments from Roche Diagnostics. DNA was extracted using a MagNaPure instrument from blood and matched plasma specimens of patients with active CMV disease (defined by another molecular assay) and from controls. Viral load was measured against Roches standards on a LightCycler instrument, followed by melt curve analysis to confirm product specificity. Dual hybridization probes targeted the CMV UL54 gene and a control sequence that was spiked before extraction. Accuracy and linearity were established using spiked DNA from the Towne-strain CMV. The assay was linear across 6 logs, and it detected CMV DNA in 67/70 blood samples (96%) from patients who were considered to have an active CMV infection, including all 67 viral loads above 208 CMV copies/mL, suggesting that it was sensitive enough to detect clinically significant infections in immunosuppressed patients. Virus levels in plasma correlated reasonably well with the levels in whole blood (r2=0.5756), suggesting that levels in either plasma or blood level were indicative of active infection. It was important to verify the calculated values by visualizing the amplification plot and using the melt curve analysis to resolve discrepancies. The LightCycler CMV assay is rapid, sensitive, and linear for quantifying CMV viral load, and it seems to be useful in the diagnosis and monitoring of affected patients.

Gastric adenocarcinoma microRNA profiles in fixed tissue and in plasma reveal cancer-associated and Epstein-Barr virus-related expression patterns.

MicroRNA expression in formalin-fixed paraffin-embedded tissue (FFPE) or plasma may add value for cancer management. The GastroGenus miR Panel was developed to measure 55 cancer-specific human microRNAs, Epstein-Barr virus (EBV)-encoded microRNAs, and controls. This Q-rtPCR panel was applied to 100 FFPEs enriched for adenocarcinoma or adjacent non-malignant mucosa, and to plasma of 31 patients. In FFPE, microRNAs upregulated in malignant versus adjacent benign gastric mucosa were hsa-miR-21, -155, -196a, -196b, -185, and -let-7i. Hsa-miR-18a, 34a, 187, -200a, -423-3p, -484, and -744 were downregulated. Plasma of cancer versus non-cancer controls had upregulated hsa-miR-23a, -103, and -221 and downregulated hsa-miR-378, -346, -486-5p, -200b, -196a, -141, and -484. EBV-infected versus uninfected cancers expressed multiple EBV-encoded microRNAs, and concomitant dysregulation of four human microRNAs suggests that viral infection may alter cellular biochemical pathways. Human microRNAs were dysregulated between malignant and benign gastric mucosa and between plasma of cancer patients and non-cancer controls. Strong association of EBV microRNA expression with known EBV status underscores the ability of microRNA technology to reflect disease biology. Expression of viral microRNAs in concert with unique human microRNAs provides novel insights into viral oncogenesis and reinforces the potential for microRNA profiles to aid in classifying gastric cancer subtypes. Pilot studies of plasma suggest the potential for a noninvasive addition to cancer diagnostics.

Epstein-Barr Virus WZhet DNA Can Induce Lytic Replication in Epithelial Cells in vitro, although WZhet Is Not Detectable in Many Human Tissues in vivo

Objective:WZhet is a rearranged and partially deleted form of the Epstein-Barr virus (EBV) genome in which the BamH1W region becomes juxtaposed with and activates BZLF1, resulting in constitutive viral replication. We tested whether WZhet induces viral replication in epithelial cells, and we studied its prevalence in a wide range of lesional tissues arising in vivo. Methods: A quantitative real-time PCR assay targeting EBV WZhet DNA was developed to measure this recombinant form of the EBV genome. Results:WZhet DNA was undetectable in any of 324 plasma or paraffin-embedded tissue samples from patients with EBV-associated and EBV-negative disorders. These included specimens from patients with Hodgkin or non-Hodgkin lymphoma, post-transplant lymphoproliferation, nasopharyngeal or gastric adenocarcinoma, and infectious mononucleosis. However, WZhet DNA was detected in vitro in EBV-infected AGS gastric cancer cells. Additionally, transient transfection of infected AGS gastric cancer cells showed that viral replication could be induced by a WZhet plasmid. Conclusion: This is the first evidence that WZhet induces the EBV lytic cycle in an epithelial cell line. Our negative findings in natural settings suggest that WZhet is a defective viral product that thrives in the absence of a host immune system but is rarely present in vivo.

Abstract 4621: Validation and calibration of next-generation sequencing to identify Epstein-Barr Virus-positive gastric cancer

Background: Gastric adenocarcinoma was recently classified by a large genomic study into four molecular subtypes, including one defined by Epstein-Barr virus (EBV)-positivity. EBV infection in tumors is conventionally assessed by in situ hybridization (ISH), but detection of viral nucleic acids by next-generation sequencing represents a potential alternative. Methods: Normalized EBV read counts were determined by whole genome, whole exome, mRNA and miRNA sequencing for 295 fresh-frozen gastric tumor samples. Formalin-fixed, paraffin-embedded tissue sections were retrieved for ISH confirmation of 13 high-EBV and 11 low-EBV cases selected at random. Results: By each sequencing method, numbers of EBV reads were bimodally distributed across tumors, with a minority having much higher counts. In pairwise comparisons, individual samples were either consistently high or consistently low by all genomic methods for which data were available. Empiric cut-offs based on molecular data of 1000 normalized reads for whole genome, 100 for exome, 4 for mRNA and 5000 for miRNA had perfect concordance identifying 26 (9%) tumors as EBV-positive. One sample tested by ISH lacked tumor cells. For the 23 tumors with EBV status determined by both approaches, EBV-positivity or -negativity by molecular testing was confirmed by EBER-ISH in all but one case (kappa = 0.91). The exception was a microsatellite instability-type cancer EBV-negative by both mRNA and miRNA sequencing, with equivocally positive ISH interpretation. Conclusions: EBV-positive gastric tumors may be accurately identified by quantifying viral sequences in genomic data. Simultaneous analyses of human and viral DNA, mRNA and miRNA could streamline tumor profiling for clinical care and research. Citation Format: M. Constanza Camargo, Reanne Bowlby, Andy Chu, Chandra S. Pedamallu, Vesteinn Thorsson, Sandra Elmore, Andrew Mungall, Adam Bass, Margaret L. Gulley, Charles S. Rabkin. Validation and calibration of next-generation sequencing to identify Epstein-Barr Virus-positive gastric cancer. [abstract]. In: Proceedings of the 106th Annual Meeting of the American Association for Cancer Research; 2015 Apr 18-22; Philadelphia, PA. Philadelphia (PA): AACR; Cancer Res 2015;75(15 Suppl):Abstract nr 4621. doi:10.1158/1538-7445.AM2015-4621