Irina Nazarenko

A novel method of HPV genotyping using Hybrid Capture® sample preparation method combined with GP5+/6+ PCR and multiplex detection on Luminex® XMAP®

A novel DNA detection assay comprising Hybrid Capture sample preparation, GP5+/6+ PCR with modifications and Luminex 100 detection was developed and applied to genotyping of human papillomavirus (HPV) in cervical samples. Target-specific sample preparation was performed using magnetic beads conjugated with Hybrid Capture (HC) antibody. DNA-RNA hybrids were formed between DNA target and RNA probes and captured on HC-beads. DNA on magnetic beads was amplified without elution using consensus GP5+/6+ PCR and then genotyped on Luminex beads using hybridization probes for the 17 high-risk HPV types 16, 18, 26, 31, 33, 35, 39, 45, 51, 52, 56, 58, 59, 66, 68, 73, 82 and an internal control. This new sequence-specific Hybrid Capture sample preparation is fast, efficient and allows direct HPV genotyping by PCR. Compared to traditional non-sequence-specific sample preparation methods, HC sample preparation demonstrated slightly better detection of multiple HPV infections. The clinical utility of this method was demonstrated on cervical samples positive for HR HPV by the Hybrid Capture 2 (hc2) screening assay.

Multiplex isothermal helicase-dependent amplification assay for detection of Chlamydia trachomatis and Neisseria gonorrhoeae

Thermophilic helicase dependent amplification (tHDA), which employs helicase to unwind double-stranded DNA at constant temperature, is a relatively new isothermal nucleic acid amplification technology. In this study, the development and optimization of a 4-plex tHDA assay for detection of Chlamydia trachomatis (CT) and Neisseria gonorrhoeae (NG) are described. tHDA is combined with sequence-specific sample preparation on magnetic beads and homogeneous endpoint fluorescence detection using dual-labeled probes. This 4-plex tHDA assay was applied to the detection of 2 genes on CT and a multicopy gene on NG in the presence of an internal control. The assay showed high analytical sensitivity and specificity of simultaneous CT/NG detection and is compatible with a wide variety of sample types and media. The isothermal reaction conditions and homogeneous endpoint detection utilized in this assay are well suited for laboratory automation and high-throughput screening applications as well as for point-of-care testing.

An HPV 16, 18, and 45 genotyping test based on Hybrid Capture technology.

BACKGROUNDnIt has been shown that women positive for HPV 16 and HPV 18 have an increased risk of high-grade cervical intraepithelial neoplasia (CIN) compared with women positive for other high-risk (HR) HPV types. In addition, HPV 18 and HPV 45 have been closely linked to aggressive and difficult to detect adenocarcinomas.nnnOBJECTIVESnTo develop a test based on the Hybrid Capture technology capable of specifically detecting the most important carcinogenic HPV types; 16, 18, and 45.nnnSTUDY DESIGNnThe assay is based on Hybrid Capture technology utilizing a mixture of short type-specific oligoribonucleotides to detect HPV types 16, 18, or 45. The assay utilizes no target amplification and shares workflow and critical reagents with the Digene HC2 HPV screening assay. Studies to evaluate specificity, performance of the test in comparison to HC2, and capability to detect a single genotype in the presence of multiple infections are described. Specificity was evaluated analytically using a panel of HR- and LR-HPV types to illustrate cross-reactivity. Performance in comparison to the HC2 test was evaluated by testing aliquots of the same prepared samples by the genotyping test and HC2. Ability to detect a single genotype during multiple infections was modeled by detecting HPV 16 plasmid in the presence of HPV 6 or HPV 31 at high copy numbers.nnnRESULTSnThe proposed genotyping assay specifically detects HPV 16, 18, and 45 with an analytical sensitivity of 5,000 copies per assay. The assay is highly specific and does not detect other tested high-risk or low-risk types at 10(8) copies per reaction. Utility of the genotyping test was demonstrated using clinical samples collected in Digene Specimen Transport Medium (STM) and results were confirmed by PCR.nnnCONCLUSIONSnThe target-amplification free assay provides a genotyping method for highly specific detection of HPV 16, 18, and 45 without the complexity of PCR technology.

HPV Genotype Detection Using Hybrid Capture Sample Preparation Combined with Whole Genome Amplification and Multiplex Detection with Luminex XMAP

Infection with a high-risk carcinogenic type of human papillomavirus (HPV) is necessary for the development of cervical cancer. The digene HC2 HPV Test (HC2) is an important screening tool but lacks genotyping capability. To address this issue, we developed an assay for the rapid genotyping of HPV in cervical specimens. The three steps of this assay include Hybrid Capture target enrichment, whole-genome amplification, and Luminex XMAP detection. The assay includes the simultaneous detection of two genomic regions from each of 17 high-risk and two low-risk HPV types most associated with disease. The assay performance was tested on HPV plasmids as well as clinical specimens. An analytical limit of detection of 100 copies or less was demonstrated for linear, circular, and integrated HPV DNA. This finding is at least 1 log lower than the HC2 assay limit of detection. There was no cross-reactivity among the HPV types up to 1,000,000 copies. There was also no substantial assay interference from substances in cervical specimens. Although the clinical performance of the assay was not formally tested, the assay had good agreement (Cohens kappa equal to 0.72) with both a PCR-based HPV genotyping assay (n = 131) and the HC2 assay (n = 502) using representative cervical specimens. This assay may be easy to automate and could be applied for the detection of other targets in future studies.

Evaluation of Chlamydia trachomatis and Neisseria gonorrhoeae Detection in Urine, Endocervical, and Vaginal Specimens by a Multiplexed Isothermal Thermophilic Helicase-Dependent Amplification (tHDA) Assay

ABSTRACT We have developed a new research assay that combines sequence-specific sample preparation and isothermal amplification for the detection of Chlamydia trachomatis and Neisseria gonorrhoeae infections. The assay targets both the omp gene and the cryptic plasmid of C. trachomatis and the multicopy opa gene of N. gonorrhoeae, which are amplified and detected in a single reaction. We evaluated the ability of the assay to detect C. trachomatis and N. gonorrhoeae infections in first-catch urine, swab, and liquid-based cytology samples. Total agreement between the new assay and APTIMA Combo 2 varied between 95.3% and 100%, depending on the sample type and target detected. Total agreement between the new assay and BD ProbeTec varied between 96.7% and 100%, depending on the sample type and target detected. The assay has a simple work flow, and endpoint results can be achieved in 3 h, including sample preparation. The assay described here was evaluated for research use and was compared to commercially available assays.

Distribution of Human papillomavirus load in clinical specimens

The information about the range and distribution of Human papillomavirus load in clinical specimens is important for the design of accurate clinical tests. The amount of Human papillomavirus in cervical specimens was estimated using the digene HC2 HPV DNA Test(®) (QIAGEN). This semi-quantitative assay is based on linear signal amplification with an analytical limit-of-detection of approximately 2500 virus copies per assay and 3-4 log dynamic range. The dynamic range of the assay was extended by a serial dilution strategy. Two large sets of positive specimens (n=501 and 569) were analyzed and 9-11% of specimens was estimated to contain more than 7 × 10(7) copies of virus. The viral load was also assessed for an assortment of specimens with known cytology diagnoses (n=9435) and histological diagnoses (n=2056). The percentage of specimens with more than 7 × 10(7) copies of virus was estimated to be 0.89 for normal cells, 4.2 for atypical cells (unknown significance), 14.31 for cells of low-grade lesions and 22.24 for cells of high-grade lesions. The viral load increased with disease severity, but its broad distribution may not support its use as a disease biomarker. This information is important for assay design and automation, where cross-reactivity and sample-to-sample contamination must be addressed rigorously.