RT-qPCR for Fecal Mature MicroRNA Quantification and Validation.

By routinely and systematically being able to perform quantitative stem-loop reverse transcriptase (RT) followed by TaqMan® minor-groove binding (MGB) probe, real-time quantitative PCR analysis on exfoliated enriched colonocytes in stool, using human (Homo sapiens, hsa) micro(mi)RNAs to monitor changes of their expression at various stages of colorectal (CRC) progression, this method allows for the reliable and quantitative diagnostic screening of colon cancer (CC). Although the expression of some miRNA genes tested in tissue shows less variability in normal or cancerous patients than in stool, the noninvasive stool by itself is well suited for CC screening. An miRNA approach using stool promises to offer more sensitivity and specificity than currently used genomic, methylomic, or proteomic methods for CC screening.To present an application of employing miRNAs as diagnostic markers for CC screening, we carried out global microarray expression studies on stool colonocytes isolated by paramagnetic beads, using Affymetrix GeneChip miRNA 3.0 Array, to select a panel of miRNAs for subsequent focused semiquantitative PCR analysis studies. We then conducted a stem-loop RT-TaqMan® MGB probes, followed by a modified real-time qPCR expression study on 20 selected miRNAs for subsequent validation of the extracted immunocaptured total small RNA isolated from stool colonocytes. Results showed 12 miRNAs (miR-7, miR-17, miR-20a, miR-21, miR-92a, miR-96, miR-106a, miR-134, miR-183, miR-196a, miR-199a-3p, and miR214) to have an increased expression in stool of CC patients, and that later TNM stages exhibited more increased expressions than adenomas, while 8 miRNAs (miR-9, miR-29b, miR-127-5p, miR-138, miR-143, miR-146a, miR-222, and miR-938) showed decreased expressions in stool of CC patients, which becomes more pronounced as the cancer progresses from early to late TNM stages (0-IV).

Absolute calibration of optical power for PDT: report of AAPM TG140.

This report is primarily concerned with methods for optical calibration of laser power for continuous wave (CW) light sources, predominantly used in photodynamic therapy (PDT). Light power calibration is very important for PDT, however, no clear standard has been established for the calibration procedure nor the requirements of power meters suitable for optical power calibration. The purposes of the report are to provide guidance for establishing calibration procedures for thermopile type power meters and establish calibration uncertainties for most commercially available detectors and readout assemblies. The authors have also provided a review of the use of various power meters for CW and pulsed optical sources, and provided recommended temporal frequencies for optical power meter calibrations and guidance for routine quality assurance procedure.

Diagnostic microRNA markers to screen for sporadic human colon cancer in stool: I. Proof of principle.

To present proof-of-principle application for employing micro(mi)RNAs as diagnostic markers for colon cancer, we carried out global microarray expression studies on stool samples obtained from fifteen individuals (three controls, and three each with TNM stage 0-1, stage 2, stage 3, and stage 4 colon cancer), using Affymetrix GeneChip miRNA 3.0 Array, to select for a panel of miRNA genes for subsequent focused semi-quantitative polymerase chain reaction (PCR) analysis studies. Microarray results showed 202 preferentially expressed miRNA genes that were either increased (141 miRNAs), or reduced (61 miRNAs) in expression. We then conducted a stem-loop reverse transcriptase (RT)-TaqMan® minor groove binding (MGB) probes, followed by a modified qPCR expression study on 20 selected miRNAs. Twelve of the miRNAs exhibited increased and 8 decreased expression in stool from 60 individuals (20 controls, 20 with tumor-lymph node-metastatic (TNM) stage 0-1, 10 with stage 2, five with stage 3, and 5 with stage 4 colon cancer) to quantitatively monitor miRNA changes at various TNM stages of colon cancer progression. We also used laser-capture microdissection (LCM) of colon mucosal epithelial tissue samples (three control samples, and three samples from each of the four stages of colon cancer, for a total of 15 samples) to find concordance or lack thereof with stool findings. The reference housekeeping pseudogene-free ribosomal gene (18S rRNA), which shows little variation in expression, was employed as a normalization standard for relative PCR quantification. Results of the PCR analyses confirmed that twelve miRNAs (miR-7, miR-17, miR-20a, miR-21, miR-92a, miR-96, miR-106a, miR-134, miR-183, miR-196a, miR-199a-3p and miR214) had an increased expression in the stool of patients with colon cancer, and that later TNM carcinoma stages exhibited a more pronounced expression than did adenomas. On the other hand, eight miRNAs (miR-9, miR-29b, miR-127-5p, miR-138, miR-143, miR-146a, miR-222 and miR-938) had decreased expression in the stool of patients with colon cancer, which was also more pronounced from early to later TNM stages. Results from colon mucosal tissues were similar to those from stool samples, although with more apparent changes in expression. Cytological studies on purified stool colonocytes that employed Giemsa staining showed 80% sensitivity for detecting tumor cells in stool smears. The performance characteristics of the test confirmed that stool is a medium well-suited for colon cancer screening, and that the quantitative changes in the expression of few mature miRNA molecules in stool associated with colon cancer progression provided for more sensitive and specific non-invasive diagnostic markers than tests currently available on the market. Thus, a larger prospective and properly randomized validation study of control individuals and patients exhibiting various stages of colon cancer progression (TNM stages 0-IV) is now needed in order to standardize test conditions, and provide a means for determining the true sensitivity and specificity of a miRNA screening approach in stool for the non-invasive detection of colon cancer, particularly at an early stage (0-I). Eventually, we will develop a chip to enhance molecular screening for colon cancer, as has been accomplished for the detection of genetically-modified organisms (GMOs) in foods.

Diagnostic microRNA markers to screen for sporadic human colon cancer in blood.

We carried out this study to present proof-of-principal application, showing that by using a global microarray expression analysis, followed by quantitative stem-loop reverse transcriptase in conjunction with TaqMan® polymerase chain reaction (PCR) analysis of micro(mi)RNA genes, on limited number of plasma and tissue samples obtained from 20 individuals (five healthy, five TNM stage 0-1 colon cancer, five stage 2 and five stage 3), we were able to quantitatively monitor miRNA changes at the various TNM stages of colon cancer progression, particularly at the early, pre-malignant adenoma stage (e.g. polyps ≥ 1 cm with high grade dysplasia). The expression of some of the tested miRNAs showed less variability in tissue than in plasma. Nevertheless, our limited preliminary data on the plasma by itself show that plasma is well-suited for screening, and that the quantitative changes in the expression of a few cell-free circulatory mature miRNA molecules in plasma, that are associated with colon cancer progression, would provide for more sensitive and specific markers than those tests currently available on the market. In addition, analysis of miRNA molecules offers a quantitative and cost-effective non-invasive diagnostic approach for screening, than currently employed methods in a prevalent cancer that can be cured if it is detected at the early TNM stages, and that becomes deadly if not diagnosed before metastasis. Thus, a larger prospective and properly randomized clinical study using plasma derived from many control individuals and at various stages of colon cancer (TNM stages 0-IV) from patients, in order to corroborate the initial results, is now urgently needed in order to allow for a statistically valid analysis, standardizing test conditions which will provide a means for determining the true sensitivity and specificity of a miRNA-screening approach. This approach, when combined with bioinformatics analysis to correlate miRNA seed data with mRNA target data, would allow for a mechanistic understanding of how miRNAs regulate mRNA gene expression, and would offer a better comprehensive diagnostic screening test for early-detection of colon cancer non-invasively.

Surface plasmon resonance (SPR) spectrometry as a tool to analyze nucleic acid-protein interactions in crude cellular extracts.

This study presents proof-of-principle application showing that label-free affinity enrichment surface plasmon resonance (SPR) biosensor binding is able to semiquantitatively detect molecular DNA-protein interactions in crude cellular extracts in a real-time ligand fishing analysis study. Crude cell extracts obtained from a confluent HT-28 human adenocarcinoma cell line, synchronized to the G(0)/G(1) phase of the cell cycle, were extracted in a chaotropic medium and cryopreserved in liquid nitrogen. Various immunoprecipitation antibodies were used against defective human excision and mismatch repair genes, hDDB2 and hMSH2, respectively, which theoretically allow for protein binding to DNA ligands in their native conformation. A set of biotinylated DNA target sequence heteroduplexes were also utilized for binding hDDB2 and hMSH2, prepared by heating a biotinylated oligonucleotide strand with an equimolar amount of the complementary strand to form a DNA duplex for hMSH2; a UV-irradiated duplex was employed for hDDB2 instead of an irradiated single-strand DNA to enhance binding. SDS was used to regenerate heteroduplex-modified chips that were used in a BIAcore 2000 SPR instrument at 25°C. Results showed that hMSH2 does not bind preferentially to the heteroduplex-complementary pair. In contrast, hDDB2 was found to bind preferentially to the UV-irradiated version of the heteroduplex-complementary pair. It is concluded that the choice of antibodies with appropriate epitopes is crucial to the success of these SPR binding studies because of enhanced specificity.

Differences in mRNA and microRNA microarray expression profiles in human colon adenocarcinoma HT-29 cells treated with either Intensity-modulated Radiation Therapy (IMRT), or Conventional Radiation Therapy (RT).

We carried out this in vitro molecular study to investigate the effect of two clinical X-irradiation modalities (a two-dimensional external beam radiotherapy referred to in this article as conventional RT, and a three dimensional conformal intensity-modulated radiation therapy (IMRT) on a colon adenocarcinoma HT-29 cell line. Cells were synchronized by serum deprivation 48 h before irradiation so that >90% of them were in the G(0)/G(1) phase of the cell cycle. Cells were allowed to recover 3 h after irradiation before total RNA extraction. Two types of arrays, namely Affymetrix Human HG U133A 2.0 oligonucleotide microarrays and Ambion mirVana bioarrays, were employed to study mRNA and microRNA expressions, respectively. Three flasks were used per irradiation dose, and an additional three unirradiated flasks served as control. Microarray data were validated by reverse transcriptase quantitative polymerase chain reaction, and proteins of some expressed genes were determined by Western blots. Results showed the existence of differences in expression profiles between the two irradiation modalities. IMRT appeared to influence expression of some DNA repair genes, whereas in conventional RT, some DNA repair and cell cycle-related genes that initially seemed to be preferentially expressed dwindled to normal levels. Earlier in vitro experiments using cell survival to study sublethal damage repair support our conclusions. Bioinformatic investigation revealed a correlation of gene expression with derepression effects of microRNA molecules. We have presented opinions as to how microRNAs might influence gene expression during radiation-induced stress and have suggested future avenues for research.