Droplet Digital Polymerase Chain Reaction (PCR) Outperforms Real-Time PCR in the Detection of Environmental DNA from an Invasive Fish Species

Doi, Hideyuki; Takahara, Teruhiko; Minamoto, Toshifumi; Matsuhashi, Saeko; Uchii, Kimiko; Yamanaka, Hiroki

doi:10.1021/acs.est.5b00253

Cited by 188 publications

(154 citation statements)

References 41 publications

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“…ddPCR has superior precision over other detection technologies to detect differential expression in miRNAs [39]. Additionally, ddPCR is more resilient to sample quality differences; has a high tolerance to PCR amplification inefficiency; and requires small sample size, which allows for high level of precision being able to capture all known sources of variation [39, 40]. …”

Section: Resultsmentioning

confidence: 99%

A Circulating microRNA Signature Predicts Age-Based Development of Lymphoma

et al. 2017

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Extensive epidemiological data have demonstrated an exponential rise in the incidence of non-Hodgkin lymphoma (NHL) that is associated with increasing age. The molecular etiology of this remains largely unknown, which impacts the effectiveness of treatment for patients. We proposed that age-dependent circulating microRNA (miRNA) signatures in the host influence diffuse large B cell lymphoma (DLBCL) development. Our objective was to examine tumor development in an age-based DLBCL system using an inventive systems biology approach. We harnessed a novel murine model of spontaneous DLBCL initiation (Smurf2-deficient) at two age groups: 3 and 15 months old. All Smurf2-deficient mice develop visible DLBCL tumor starting at 15 months of age. Total miRNA was isolated from serum, bone marrow and spleen and were collected for all age groups for Smurf2-deficient mice and age-matched wild-type C57BL/6 mice. Using systems biology techniques, we identified a list of 10 circulating miRNAs being regulated in both the spleen and bone marrow that were present in DLBCL forming mice starting at 3 months of age that were not present in the control mice. Furthermore, this miRNA signature was found to occur circulating in the blood and it strongly impacted JUN and MYC oncogenic signaling. In addition, quantification of the miRNA signature was performed via Droplet Digital PCR technology. It was discovered that a key miRNA signature circulates throughout a host prior to the formation of a tumor starting at 3 months old, which becomes further modulated by age and yielded calculation of a ‘carcinogenic risk score’. This novel age-based circulating miRNA signature may potentially be leveraged as a DLBCL risk profile at a young age to predict future lymphoma development or disease progression as well as for potential innovative miRNA-based targeted therapeutic strategies in lymphoma.

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Section: Resultsmentioning

confidence: 99%

A Circulating microRNA Signature Predicts Age-Based Development of Lymphoma

et al. 2017

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“…At higher concentrations (>200 copies/μL), recent research has shown that qPCR and ddPCR are equivalent at detecting eDNA 37 however, ddPCR can detect eDNA significantly better at very low concentrations (<3 copies/mL) 12, 25, 38 . Using the same primers and Taqman probe from qPCR, target DNA was randomly allocated on to discrete droplets using microfluidics and then each of the samples, containing 10,000 to 20,000 nanodroplets via microfluidics that are then thermally-cycled (see Nathan et al .…”

Section: Methodsmentioning

confidence: 99%

Controls on eDNA movement in streams: Transport, Retention, and Resuspension

Shogren

Tank

Andruszkiewicz

et al. 2017

Sci Rep

248

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Advances in detection of genetic material from species in aquatic ecosystems, including environmental DNA (eDNA), have improved species monitoring and management. eDNA from target species can readily move in streams and rivers and the goal is to measure it, and with that infer where and how abundant species are, adding great value to delimiting species invasions, monitoring and protecting rare species, and estimating biodiversity. To date, we lack an integrated framework that identifies environmental factors that control eDNA movement in realistic, complex, and heterogeneous flowing waters. To this end, using an empirical approach and a simple conceptual model, we propose a framework of how eDNA is transported, retained, and resuspended in stream systems. Such an understanding of eDNA dispersal in streams will be essential for designing optimized sampling protocols and subsequently estimating biomass or organismal abundance. We also discuss guiding principles for more effective use of eDNA methods, highlighting the necessity of understanding these parameters for use in future predictive modeling of eDNA transport.

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“…In the pond experiment, we failed to find any significant differences in the detection rate of carp eDNA by the two precipitation methods, when the reaction volume was the same, perhaps because the detection rate was only determined by the presence or absence of a few copies of target eDNA (Doi et al ). However, in samples with low eDNA concentrations, the isopropanol precipitation method would exhibit a higher detection rate, owing to a higher amount of recovered eDNA.…”

Section: Discussionmentioning

confidence: 88%

“…The environmental DNA (eDNA) method can be used to estimate the distribution of aquatic organisms, using DNA extracted from the water of aquatic habitats (Ficetola et al ; Rees et al ; Goldberg et al ; Thomsen and Willerslev ). Since the eDNA method is an easy‐to‐use approach, which only requires collecting water from the field, it has been applied to diverse species in various ecosystems, including ponds and lakes (e.g., Ficetola et al ; Thomsen et al ; Jerde et al ; Takahara et al ; Doi et al ; Uchii et al ), rivers (Minamoto et al ; Pilliod et al ; Fukumoto et al ; Wilcox et al ; Yamanaka and Minamoto ), and marine habitats (Mahon et al ; Miya et al ; Yamamoto et al ).…”

mentioning

confidence: 99%

Isopropanol precipitation method for collecting fish environmental DNA

Doi

Uchii

Matsuhashi

et al. 2017

Limnology & Ocean Methods

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The environmental DNA (eDNA) method has been used to estimate the distributions of aquatic species, and both ethanol precipitation and filtration‐based methods are commonly employed to capture eDNA from sampled water. Although filtration‐based methods can capture more eDNA than that by ethanol precipitation, by processing larger volumes of water (e.g., 1 L vs. 15 mL), ethanol precipitation can immediately preserve eDNA on site and ease downstream processing, which are especially advantageous for eDNA studies conducted with limited resources, such as electric equipment, labor, and time. However, the ethanol precipitation method is limited by small volume of water that can be processed (i.e., 15 mL in a reaction volume of 50 mL). As an alternative, isopropanol could potentially be used to increase the volume of sample water processed, since lower volumes of isopropanol are required for precipitation. Therefore, in the present study, we compared the copy numbers of carp eDNA captured using isopropanol and ethanol precipitation in both mesocosm and field experiments. In both cases, we found that isopropanol precipitation recovered double the amount of eDNA recovered by ethanol precipitation, when the reaction volumes were equal. Therefore, isopropanol precipitation is a superior option for eDNA capture when surveys are conducted under resource‐limited conditions.

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Droplet Digital Polymerase Chain Reaction (PCR) Outperforms Real-Time PCR in the Detection of Environmental DNA from an Invasive Fish Species

Cited by 188 publications

References 41 publications

A Circulating microRNA Signature Predicts Age-Based Development of Lymphoma

A Circulating microRNA Signature Predicts Age-Based Development of Lymphoma

Controls on eDNA movement in streams: Transport, Retention, and Resuspension

Isopropanol precipitation method for collecting fish environmental DNA

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