Analytical Validation of a Novel MicroRNA Panel for Risk Stratification of Cognitive Impairment.

We have been developing a novel approach to identify cognitive impairment-related biomarkers by profiling brain-enriched and inflammation-associated microRNA (miRNA) in plasma specimens of cognitively unimpaired and cognitively impaired patients. Here, we present an analytical validation of the novel miRNA panel, CogniMIR®, using two competing quantitative PCR technologies for the expression analysis of 24 target miRNAs. Total RNA from the plasma specimens was isolated using the MagMAX mirVana Kit, and RT-qPCR was performed using stem-loop-based TaqMan and LNA-based qPCR assays. Evaluation of RNA dilution series for our target 24 miRNAs, performed by two operators on two different days, demonstrated that all CogniMIR® panel miRNAs can be reliably and consistently detected by both qPCR technologies, with sample input as low as 20 copies in a qPCR reaction. Intra-run and inter-run repeatability and reproducibility analyses using RNA specimens demonstrated that both operators generated repeatable and consistent Cts, with R2 values of 0.94 to 0.99 and 0.96 to 0.97, respectively. The study results clearly indicate the suitability of miRNA profiling of plasma specimens using either of the qPCR technologies. However, the LNA-based qPCR technology appears to be more operationally friendly and better suited for a CAP/CLIA-certified clinical laboratory.

Brain-enriched microRNAs circulating in plasma as novel biomarkers for Rett syndrome.

Rett syndrome (RTT) is a severe neurodevelopmental disorder caused by mutations in the X-linked gene MECP2 (methyl-CpG-binding protein 2). Minimally invasive and accurate biomarkers of disease progression and treatment response could facilitate screening of therapeutic compounds in animal models, enrollment of better-defined participants into clinical trials, and treatment monitoring. In this study, we used a targeted approach based on analysis of brain-enriched microRNAs (miRNAs) circulating in plasma to identify miRNA biomarkers of RTT using Mecp2-mutant mice as a model system and human plasma samples. An "miRNA pair" approach, i.e. the ratio between two miRNAs, was used for data normalization. Specific miRNA pairs and their combinations (classifiers) analyzed in plasma differentiated wild-type from Mecp2 male and female mice with >90% accuracy. Individual miRNA pairs were more effective in distinguishing male (homozygous) animals than female (heterozygous) animals, suggesting that disease severity correlated with the levels of the miRNA biomarkers. In the human study, 30 RTT patients were compared with age-matched controls. The results of this study showed that miRNA classifiers were able to differentiate RTT patients from controls with 85-100% sensitivity. In addition, a comparison of various age groups demonstrated that the dynamics in levels of miRNAs appear to be associated with disease development (involvement of liver, muscle and lipid metabolism in the pathology). Importantly, certain miRNA biomarker pairs were common to both the animal models and human subjects, indicating the similarity between the underlying pathological processes. The data generated in this feasibility study suggest that circulating miRNAs have the potential to be developed as markers of RTT progression and treatment response. Larger clinical studies are needed to further evaluate the findings presented here.

Age- and sex-dependent changes in levels of circulating brain-enriched microRNAs during normal aging.

Aging is a major risk factor for many common and life-threatening pathologies. The development of reliable biomarkers of aging should lead to a better understanding of aging-associated processes and facilitate the development of therapeutic regimens that delay aging. Levels of 38 brain-enriched microRNAs (miRNA) circulating in plasma were measured by quantitative RT-PCR in two age groups: 26-35 and 56-65 years old. An miRNA-pair approach was used for data normalization and determination of effective miRNA biomarker ratios. Nineteen miRNAs, comprising miRNA pairs and pair combinations (classifiers) that effectively differentiated the age and sex (individual pairs: 74-95% and 68-95%, respectively; classifiers: up to 100% accuracy) groups, were selected for further analysis of plasma samples from 5 donor age groups: 26-35, 36-45, 46-55, 56-65 and 66-75 years old. Dynamic changes in the plasma concentrations of certain miRNAs occurred at different ages in females and males, with peaks in the 46-55-year-old and 56-65-year-old groups, respectively. This finding suggests that the changes in miRNA levels can reflect centrally regulated processes, including changes in hormone levels during menopause. Certain miRNAs and miRNA pairs correlated with age in the sex-stratified groups at different ages and should be investigated further as potentially promising biomarkers of brain aging.

Aging and aging-associated diseases: a microRNA-based endocrine regulation hypothesis.

Although there are numerous hypotheses explaining the nature of aging and associated processes, two concepts are dominant: (i) aging is a result of cell-autonomous processes, such as the accumulation of DNA mutations, aberrant methylations, protein defects, and shortening of telomeres, leading to either inhibition of cellular proliferation and death of non-dividing terminally differentiated cells or tumor development; (ii) aging is a result of a central program that is switched on at a specific stage of organismic development. The microRNA-based endocrine regulation hypothesis combines the two above concepts by proposing central regulation of cell death occurrences via hypothalamus-pituitary gland (PG)-secreted miRNA hormones, the expression and/or secretion of which are regulated by sex hormones. This hypothesis explains such well-known phenomena as inverse comorbidity of either cancer or Alzheimer's (AD) and other neurodegenerative diseases; higher AD morbidity and lower frequency of many common types of cancer in women vs. men; higher risk of early AD and lower risk of cancer in subjects with Down syndrome; longer life expectancy in women vs. men and much lower sex-dependent differences, if any, in other mammals; increased lifespans due to hypophysectomy or PG hypofunction; and parabiotic effects of blood or plasma transfusions between young and old animals.

Circulating brain-enriched microRNAs as novel biomarkers for detection and differentiation of neurodegenerative diseases.

BACKGROUND: Minimally invasive specific biomarkers of neurodegenerative diseases (NDs) would facilitate patient selection and disease progression monitoring. We describe the assessment of circulating brain-enriched microRNAs as potential biomarkers for Alzheimer's disease (AD), frontotemporal dementia (FTD), Parkinson's disease (PD), and amyotrophic lateral sclerosis (ALS). METHODS: In this case-control study, the plasma samples were collected from 250 research participants with a clinical diagnosis of AD, FTD, PD, and ALS, as well as from age- and sex-matched control subjects (n = 50 for each group), recruited from 2003 to 2015 at the University of Pennsylvania Health System, including the Alzheimer's Disease Center, the Parkinson's Disease and Movement Disorders Center, the Frontotemporal Degeneration Center, and the Amyotrophic Lateral Sclerosis Clinic. Each group was randomly divided into training and confirmation sets of equal size. To evaluate the potential of circulating microRNAs enriched in specific brain regions affected by NDs and present in synapses as biomarkers of NDs, the levels of 37 brain-enriched and inflammation-associated microRNAs in the plasma of all participants were measured using individual qRT-PCR. A "microRNA pair" approach was used for data normalization. RESULTS: MicroRNA pairs and their combinations (classifiers) capable of differentiating NDs from control and from each other were defined using independently and jointly analyzed training and confirmation datasets. AD, PD, FTD, and ALS are differentiated from control with accuracy of 0.89, 0.90, 0.88, and 0.83 (AUCs, 0.96, 0.96, 0.94, and 0.93), respectively; NDs are differentiated from each other with accuracy ranging from 0.77 (AUC, 0.87) for AD vs. FTD to 0.93 (AUC, 0.98) for AD vs. ALS. The data further indicate sex dependence of some microRNA markers. The average increase in accuracy in distinguishing ND from control for all and male/female groups is 0.06; the largest increase is for ALS, from 0.83 for all participants to 0.92/0.98 for male/female participants. CONCLUSIONS: The work presented here suggests the possibility of developing microRNA-based diagnostics for detection and differentiation of NDs. Larger multicenter clinical studies are needed to further evaluate circulating brain-enriched microRNAs as biomarkers for NDs and to investigate their association with other ND biomarkers in clinical trial settings.

Universal screening test based on analysis of circulating organ-enriched microRNAs: a novel approach to diagnostic screening.

Early disease detection leads to more effective and cost-efficient treatment. It is especially important for cancer and neurodegenerative diseases, because progression of these pathologies leads to significant and frequently irreversible changes in underlying pathophysiological processes. At the same time, the development of specific screening tests for detection of each of the hundreds of human pathologies in asymptomatic stage may be impractical. Here, we discuss a recently proposed concept: the development of minimally invasive Universal Screening Test (UST) based on analysis of organ-enriched microRNAs in plasma and other bodily fluids. The UST is designed to detect the presence of a pathology in particular organ systems, organs, tissues or cell types without diagnosing a specific disease. Once the pathology is detected, more specific, and if necessary invasive and expensive, tests can be administered to precisely define the nature of the disease. Here, we discuss recent studies and analyze the data supporting the UST approach.

Analysis of organ-enriched microRNAs in plasma as an approach to development of Universal Screening Test: feasibility study.

BACKGROUND: Early disease detection with a minimally invasive screening test will significantly increase effectiveness and decrease the cost of treatment. Here we propose a framework of a novel approach - Universal Screening Test (UST) for the detection of pathological processes in a particular organ system, organ, or tissue by RT-qPCR analysis of circulating cell-free miRNAs in plasma. As the first step towards assessing the feasibility of this concept, the present study was designed to analyze whether the same microRNAs (miRNAs) can detect various diseases of a particular organ system. METHODS: RNA was extracted from plasma using Trizol treatment and silica binding. Levels of miRNAs were measured by single target RT-qPCR. The following innovations have been tested and proven effective: (i) the use of organ system/organ/tissue-enriched miRNAs; (ii) the use of miRNAs associated with broad disease categories, such as cancer and inflammation, in combination with the organ-enriched miRNAs; and (iii) the use of "miRNA pairs" for selecting miRNA combinations with the highest sensitivity and specificity. RESULTS: Here we report biomarker miRNA pairs effectively differentiating (i) patients with pulmonary system diseases (asthma, pneumonia and non-small cell lung cancer) and gastrointestinal (GI) system diseases (Crohn's disease, stages I/II esophageal, gastric and colon cancers) from controls, each with 95% accuracy; (ii) patients with a pathology of the pulmonary system from patients with a pathology of the GI system with 94% accuracy; and (iii) cancer patients (stages I/II esophageal, gastric, colon cancers, or non-small cell lung cancer) from patients with inflammatory diseases (asthma, pneumonia, or Crohn's disease) with 93%-95% accuracy. CONCLUSIONS: The results obtained in the present study, along with the data reported by us and others previously, are encouraging and lay the ground for further investigation of the described approach for UST development.

Plasma microRNA biomarkers for detection of mild cognitive impairment: biomarker validation study.

A minimally invasive test for early detection and monitoring of Alzheimer's and other neurodegenerative diseases is a highly unmet need for drug development and planning of patient care. Mild Cognitive Impairment (MCI) is a syndrome characteristic of early stages of many neurodegenerative diseases. Recently, we have identified two sets of circulating brain-enriched miRNAs, the miR-132 family (miR-128, miR-132, miR-874) normalized per miR-491-5p and the miR-134 family (miR-134, miR-323-3p, miR-382) normalized per miR-370, capable of differentiating MCI from age-matched control (AMC) with high accuracy. Here we report a biomarker validation study of the identified miRNA pairs using larger independent sets of age- and gender- matched plasma samples. The biomarker pairs detected MCI with sensitivity, specificity and overall accuracy similar to those obtained in the first study. The miR-132 family biomarkers differentiated MCI from AMC with 84%-94% sensitivity and 96%-98% specificity, and the miR-134 family biomarkers demonstrated 74%-88% sensitivity and 80-92% specificity. When miRNAs of the same family were combined, miR-132 and miR-134 family biomarkers demonstrated 96% and 87% overall accuracy, respectively. No statistically significant differences in the biomarker concentrations in samples obtained from male and female subjects were observed for either MCI or AMC. The present study also demonstrated that the highest sensitivity and specificity are achieved with pairs of miRNAs whose concentrations in plasma are highly correlated.

Circulating cell-free microRNA as biomarkers for screening, diagnosis and monitoring of neurodegenerative diseases and other neurologic pathologies.

Many neurodegenerative diseases, such as Alzheimer's disease, Parkinson disease, vascular and frontotemporal dementias, as well as other chronic neurological pathologies, are characterized by slow development with a long asymptomatic period followed by a stage with mild clinical symptoms. As a consequence, these serious pathologies are diagnosed late in the course of a disease, when massive death of neurons has already occurred and effective therapeutic intervention is problematic. Thus, the development of screening tests capable of detecting neurodegenerative diseases during early, preferably asymptomatic, stages is a high unmet need. Since such tests are to be used for screening of large populations, they should be non-invasive and relatively inexpensive. Further, while subjects identified by screening tests can be further tested with more invasive and expensive methods, e.g., analysis of cerebrospinal fluid or imaging techniques, to be of practical utility screening tests should have high sensitivity and specificity. In this review, we discuss advantages and disadvantages of various approaches to developing screening tests based on analysis of circulating cell-free microRNA (miRNA). Applications of circulating miRNA-based tests for diagnosis of acute and chronic brain pathologies, for research of normal brain aging, and for disease and treatment monitoring are also discussed.

Plasma microRNA biomarkers for detection of mild cognitive impairment.

Early stages of many neurodegenerative diseases, such as Alzheimer's disease, vascular and frontotemporal dementia, and Parkinson's disease, are frequently associated with Mild Cognitive Impairment (MCI). A minimally invasive screening test for early detection of MCI may be used to select optimal patient groups in clinical trials, to monitor disease progression and response to treatment, and to better plan patient clinical care. Here, we examined the feasibility of using pairs of brain-enriched plasma microRNA (miRNA), at least one of which is enriched in synapses and neurites, as biomarkers that could differentiate patients with MCI from age-matched controls. The identified biomarker pairs fall into two sets: the "miR-132 family" (miR-128/miR-491-5p, miR-132/miR-491-5p and mir-874/miR-491-5p) and the "miR-134 family" (miR-134/miR-370, miR-323-3p/miR-370 and miR-382/miR-370). The area under the Receiver-Operating Characteristic curve for the differentiation of MCI from controls using these biomarker pairs is 0.91-0.95, with sensitivity and specificity at 79%-100% (miR-132 family) and 79%-95% (miR-134 family), and p〈0.001. In a separate longitudinal study, the identified miRNA biomarker pairs successfully detected MCI in majority of patients at asymptomatic stage 1-5 years prior to clinical diagnosis. The reported biomarker pairs also appear useful for detecting age-related brain changes. Further testing in a larger study is necessary for validation of these results.

Optimization of transrenal DNA analysis: detection of fetal DNA in maternal urine.

BACKGROUND: Fragments of DNA from cells dying throughout the body are detectable in urine (transrenal DNA, or Tr-DNA). Our goal was the optimization of Tr-DNA isolation and detection techniques, using as a model the analysis of fetal DNA in maternal urine. METHODS: We isolated urinary DNA using a traditional silica-based method and using a new technique based on adsorption of cell-free nucleic acids on Q-Sepharose resin. The presence of Y chromosome-specific SRY (sex-determining region Y) sequences in urine of pregnant women was detected by conventional and real-time PCR using primers/probe sets designed for 25-, 39-, 65-, and 88-bp PCR targets. RESULTS: Method of DNA isolation and PCR target size affected fetal Tr-DNA detection. Assay diagnostic sensitivity increases as the PCR target is shortened. Shorter DNA fragments (50-150 bp) could be isolated by Q-resin-based technique, which also facilitated fetal Tr-DNA analysis. Using DNA isolated by Q-resin-based method and an "ultrashort" DNA target, we successfully detected SRY sequences in 78 of 82 urine samples from women pregnant with male fetuses (positive predictive value 87.6%). Eleven of 91 urine samples from women pregnant with female fetuses produced SRY false-positive results (negative predictive value 95.2%). CONCLUSIONS: Single-copy fetal DNA sequences can be successfully detected in the urine of pregnant women when adequate methods for DNA isolation and analysis are applied. Strong precautions against sample contamination with male cells and DNA are necessary to avoid false-positive results.

Transrenal nucleic acids: from proof of principle to clinical tests.

In spite of numerous publications on potential diagnostic application of circulating DNA and transrenal nucleic acid (Tr-NA) analysis, few, if any, tests based on this technology are available in clinical labs. This delay in test development and implementation is caused, at least in part, by the deficit in robust methods for isolation of short nucleic acid fragments from bodily fluids, as well as in techniques for analyzing these fragments. We have developed a new anion exchanger-based method for the isolation of cell-free nucleic acid fragments from large volumes of bodily fluids, and analyzed these fragments by PCR techniques specially designed to amplify "ultrashort" templates. The combination of these two techniques not only revealed the presence in urine of 10-150 bases or bp DNA and RNA fragments in addition to previously observed 150-200-bp DNA fragments and high molecular weight DNA, but also significantly increased the sensitivity of Tr-DNA detection. Additionally, we detected in urine a variety of miRNAs, including those excreted transrenally, thereby opening new diagnostic possibilities for Tr-NA analysis.

Novel applications of polymerase chain reaction to urinary nucleic acid analysis.

DNA fragments from cells that have died throughout the body not only appear in the bloodstream but also cross the kidney barrier into the urine. The relatively low molecular weight (150-200 bp) of this Transrenal DNA should be considered when deciding on methods of isolation and analysis. In particular, if polymerase chain reaction (PCR) is used for amplification and detection of specific sequences, then the reduction of amplicon size will significantly enhance sensitivity. Detection of DNA mutations is also made more difficult by the presence of a large excess of a wild-type allele. Using K-RAS mutations as an example, two ways around this problem--enriched PCR and stencil-aided mutation analysis-are described, based on selective pre-PCR elimination of wild-type sequences.

Transrenal DNA testing: progress and perspectives.

Transrenal DNA (Tr-DNA) is a recently discovered class of extracellular urinary DNA that originates from cells dying throughout the body. Postapoptotic DNA is known to appear in the circulating plasma, but it is now recognized that a portion of these fragments cross the kidney barrier and appear in urine in the form of 150-200-bp fragments. Tr-DNA containing fetal sequences has been isolated from the urine of pregnant women, tumor-specific mutations have been detected in Tr-DNA from patients with colon and pancreatic tumors, and donor DNA has been found in Tr-DNA isolated from recipient urine. Furthermore, proviral HIV DNA, bacterial and parasite DNA sequences have been detected in Tr-DNA from infected patients. Potential applications of Tr-DNA-based tests cover a very broad area of molecular diagnostics and genetic testing, including prenatal detection of inherited diseases, tumor diagnostics and therapeutic monitoring and detection of infectious agents. The Tr-DNA test is expected to have utility in treatment monitoring, transplantation monitoring, drug development and broad public health screening, where a noninvasive, common-platform diagnostic technology has particular value. This review describes some of the highlights of Tr-DNA technology applications, advantages over existing technologies and potential problems anticipated in test development.

Transrenal DNA as a diagnostic tool: important technical notes.

A small portion of DNA from apoptotic cells escapes complete degradation, appears in blood as oligonucleosomal-size fragments, is excreted in the urine, and can be used for diagnostic purposes. More detailed study revealed that transrenal DNA (Tr-DNA) belongs to a relatively low molecular-weight (150-250 bp) fraction, thereby requiring more careful attention to methods employed for purification and analysis. For example, here it is demonstrated that the QIAamp blood kit purifies primarily high molecular-weight DNA from serum, whereas the Guanidine/Promega Wizard Resin (GITC/WR) method purifies primarily low molecular-weight DNA. As a result, sensitivity in detection of K-RAS mutations in serum of patients with colorectal tumors is significantly higher with DNA isolated with the GITC/WR method than with the QIAamp kit. Amplicon size is also extremely important in analysis of Tr-DNA, because the shorter the amplicon, the higher is the sensitivity of biomarker detection in Tr-DNA. One hundred fifty-seven and 87 bp amplicons were employed for detection of mutant K-RAS in DNA isolated from 0.1 mL of urine obtained from 15 patients with pancreatic cancer. Mutant K-RAS was found in Tr-DNA of 3 and 10 patients with the long and short amplicons, respectively. The sensitivity and specificity of detection of mutant sequences are reduced in the presence of high excess of a respective wild-type allele, but they can be significantly increased through application of enriched polymerase chain reaction (PCR), peptide nucleic acid (PNA) clamped PCR, and/or stencil-aided mutation analysis (SAMA), based on selective pre-PCR elimination of wild-type sequences.

Human urine contains small, 150 to 250 nucleotide-sized, soluble DNA derived from the circulation and may be useful in the detection of colorectal cancer.

Human urine has been shown to possess submicrogram per milliliter amounts of DNA. We show here that DNA isolated from human urine resolves into two size categories: the large species, greater than 1 kb, being predominantly cell associated and heterogeneous in size, and the smaller, between 150 to 250 bp, being mostly non-cell associated. We showed that the low molecular weight class of urine DNA is derived from the circulation, by comparing the mutated K-ras sequences present in DNA isolated from tumor, blood, and urine derived from an individual with a colorectal carcinoma (CRC) containing a mutation in codon 12 of the K-ras proto-oncogene. In the urine, mutated K-ras sequences were abundant in the low molecular weight species, but far less abundant in the large molecular weight-derived DNA. Finally, the possibility that detection of mutant K-ras sequences in DNA derived from the urine correlates with the occurrence of a diagnosis of CRC and polyps that contain mutant K-ras was explored in a blinded study. There was an 83% concurrence of mutated DNA detected in urine and its corresponding disease tissue from the same individuals, when paired urine and tissue sections from 20 subjects with either CRC or adenomatous polyps were analyzed for K-ras mutation. The possibility that the source of the trans renal DNA is apoptotic cells, and the potential use of this finding for cancer detection and monitoring is discussed.

Apoptosis in the myocardium: much is still expected.

Apoptosis continues to be a controversial concept and subject of debate among scientists regarding its value as the basis for new therapeutic strategies. Today, it is widely accepted that the death of cardiac myocytes under a variety of conditions appears to be apoptotic based on a variety of criteria. However, the significance of these observations and how the insights into apoptotic molecular pathways may provide novel therapeutic targets remains to be determined. It is important to reconsider the pertinent underlying mechanisms of apoptosis regulation, and how these molecular pathways may be viewed in the functioning, intact heart. This knowledge can be applied in pursuit of practical goals in a search for new ways to prevent myocardial damage following such injuries as ischaemia/reperfusion or exposure to cardiotoxic drugs. Although recent literature contains reports of positive findings, there has not yet been a rigorous application of the model of apoptosis in the myocardium, and the potential for development of new therapeutic strategies is not yet understood.