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Comparing the MicroRNA Spectrum between Serum and Plasma

  • Kai Wang ,

    kwang@systemsbiology.org

    Affiliation Institute for Systems Biology, Seattle, Washington, United States of America

  • Yue Yuan,

    Affiliation Institute for Systems Biology, Seattle, Washington, United States of America

  • Ji-Hoon Cho,

    Affiliation Institute for Systems Biology, Seattle, Washington, United States of America

  • Sara McClarty,

    Affiliation Institute for Systems Biology, Seattle, Washington, United States of America

  • David Baxter,

    Affiliation Institute for Systems Biology, Seattle, Washington, United States of America

  • David J. Galas

    Affiliations Institute for Systems Biology, Seattle, Washington, United States of America, Luxembourg Center for Systems Biomedicine, University of Luxembourg, Luxembourg City, Luxembourg

Abstract

MicroRNAs (miRNAs) are small, non-coding RNAs that regulate various biological processes, primarily through interaction with messenger RNAs. The levels of specific, circulating miRNAs in blood have been shown to associate with various pathological conditions including cancers. These miRNAs have great potential as biomarkers for various pathophysiological conditions. In this study we focused on different sample types’ effects on the spectrum of circulating miRNA in blood. Using serum and corresponding plasma samples from the same individuals, we observed higher miRNA concentrations in serum samples compared to the corresponding plasma samples. The difference between serum and plasma miRNA concentration showed some associations with miRNA from platelets, which may indicate that the coagulation process may affect the spectrum of extracellular miRNA in blood. Several miRNAs also showed platform dependent variations in measurements. Our results suggest that there are a number of factors that might affect the measurement of circulating miRNA concentration. Caution must be taken when comparing miRNA data generated from different sample types or measurement platforms.

Introduction

Measuring the levels of specific analytes in bodily fluids, especially serum or plasma prepared from blood, is the most commonly used method in diagnosis. It is relatively noninvasive and in certain cases, with proper training and supervision, can be self-administered by patients for disease management (e.g. a blood sugar test). However, most of the current blood biomarkers are inadequate in specificity and sensitivity for definitive disease diagnosis. One of the major foci in biomedical research in the past few decades has been to identify biomarkers, or panels of biomarkers, in body fluids with clear disease association. Most of these activities are centered on identifying protein-based biomarkers; however, promise is still unfulfilled.

MicroRNAs (miRNAs) are endogenous 17 to 23 nucleotide-long noncoding regulatory RNA molecules that modulate cellular messenger RNA (mRNA) and protein levels by interacting with specific mRNAs, usually at the 3′ untranslated region (UTR), through partial sequence complementation [1], [2]. Thus far, over 1,000 human miRNAs have been identified (miRBase, www.mirbase.org). Recently, a significant number of miRNAs have also been found outside of the cells, and the levels of some of these extracellular miRNAs in circulation have been linked to different pathophysiological conditions. Examples of this include the associations of miR-141 with prostate cancer, miR-499 with myocardial infarction, and miR-122 with drug-induced liver injury [3][7]. These findings raise the possibility of using the levels of specific miRNAs in circulation as biomarkers for different pathological conditions [8][12]. Compared to protein-based biomarkers, miRNA offers several advantages: the complexity of miRNA is much lower than that of proteins; the miRNAs are stable in various bodily fluids; the sequences of many miRNAs are conserved among different clinically relevant species; the expression of some miRNAs are restricted to specific tissues or biological stages. The levels of miRNAs can also be easily measured by various commonly used laboratory methods, including assorted signal amplification strategies [8].

Despite significant progress in identifying the association of specific circulating miRNAs in various diseases, factors that may affect the measurement of circulating miRNA concentrations have yet to be fully addressed. Previous reports on the exportation of miRNAs from cells raised the prospect that plasma and serum might exhibit some differences in their miRNA content. We obtained serum and corresponding plasma samples from 12 healthy individuals to investigate the possible effects of different types of blood sample preparation on miRNA measurement. Our results suggested that different blood sample preparation methods might affect the concentration measurement of individual circulating miRNAs.

Results

Serum and plasma samples from 12 individuals, 6 males and 6 females, with ages ranging from 22 to 41, were used for our measurements. Various blood cell components were also collected from 6 (3 males and 3 females) of the 12 donors (Table 1). The general sample information and concentrations of isolated RNA are listed on Table 1. No significant association between RNA concentration with either the gender or the age of the donor was observed. However the sera showed a higher RNA concentration than the corresponding plasma samples (with a p value of 0.0312 calculated by two-sample t-test). WBC, RBC, and platelets had much higher RNA concentrations than either plasma or serum, as expected. Unlike the RNA from RBC or WBC, the pattern of platelet total RNA is similar to serum and plasma on bioanalyzer (Figure S1).

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Table 1. General information on samples and measurement results.

https://doi.org/10.1371/journal.pone.0041561.t001

Plasma and Serum Contained Significant Number of miRNAs

a) miRNA measured by Taqman card.

The serum and plasma miRNA spectrum from 6 normal individuals (3 males and 3 females) was profiled with Taqman miRNA panel (Table 1). The number of detectable miRNA species from these samples ranged from 137 (in ID-6 plasma) to 234 (in ID-1 plasma) (Table 1). 106 miRNAs could be seen in all plasma samples, 118 in all serum samples, and 98 miRNAs could be seen in all plasma and serum samples tested (Table S1). No significant correlation between the number of detectable miRNA species with either the gender of the donor, the type of sample used (serum or plasma), or the RNA concentration was observed. Based on the 40-Ct values, there is no statistically significant difference between serum and plasma’s miRNA concentrations (p-value = 0.3991 from two-sample t-test) (Table S1 and Figure 1A). However, the serum samples always showed higher concentrations than plasma when we measured specific miRNA levels with individual QPCR Taqman primers regardless of the results from the initial Taqman card profiling, examples are shown in Figure 2. Based on the Taqman card measurement results, the most abundant miRNA species was miR-223 for all the serum samples and one of the plasma samples tested (Table S3).

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Figure 1. Comparing the individual miRNA concentrations between serum and plasma.

The average concentrations (40-Ct values) of detected miRNAs in all serum and plasma samples within each platform were plotted – each point represents the average from all individuals of a specific miRNA. The Y-axis represents the average miRNA concentrations in serum and X-axis is the average concentration of corresponding plasma. The results from Taqman are showed in panel A and Exiqon are showed in panel B.

https://doi.org/10.1371/journal.pone.0041561.g001

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Figure 2. Examples of miRNA concentration differences between serum and plasma using individual Taqman QPCR primers.

The sample IDs were listed on the X-axis and the miRNA concentrations were displayed on the Y-axis (in 40-Ct value). The miRNA IDs were indicated on top of the graph. Open bars represent plasma samples and the solid bars represent the corresponding serum samples. The values of standard derivation were obtained from three independent measurements. The original measurement results from Taqman card showed higher 40-Ct values since a pre-amplification step was employed. Two-way ANOVA was used to determine the statistical significance of the miRNA concentration differences between serum and plasma (p-values are shown in the figure).

https://doi.org/10.1371/journal.pone.0041561.g002

The coefficient of variation (standard deviation/mean of concentration) for individual miRNA across samples from different donors was determined. Among the 6 plasma samples, miR-101 showed the highest concentration variation and miR-185 had the most consistent concentration (Table 2). In sera, miR-576-3p and miR-345 had the highest and lowest concentration variations, respectively. Interestingly, the levels of MammU6, RNU44 (SNORD 44) and RNU48 (SNORD48) which had been used to normalize miRNA concentration measurements were not consistently detected in the serum and plasma samples tested. In addition, the concentrations of these RNAs also showed significant variations among samples (Table S1).

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Table 2. The list of miRNAs with the most and least concentration variations in serum and plasma samples and measurement platforms.

https://doi.org/10.1371/journal.pone.0041561.t002

b) miRNA measured by Exiqon panels.

With Exiqon QPCR panels, the number of detectable miRNAs among different samples ranged from 123 to 296, with an average of 181 in plasma and 204 in serum. Among them, 90 miRNAs were shared in all plasma samples, 99 in all serum samples, and 83 in both (Table 1 and Table S2). Similar to Taqman results, no significant association between the numbers of detectable miRNA in relation to either gender or RNA concentrations was observed. Serum has more detectable miRNAs than plasma (Table 1). Most of the miRNAs in serum showed higher concentrations than the corresponding plasma samples (with a p-value = 0.0379 from two-sample t-test) (Table S2 and Figure 1B). The higher concentration of miRNAs in serum samples was also demonstrated with individual QPCR primers on some of the miRNAs, examples are shown in Figure 3. Except for one serum sample (sample 55-29515), miR-451 was the most abundant miRNA species based on the results of Exiqon miRNA QPCR panel (Table S3).

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Figure 3. Examples of miRNA concentration differences between serum and plasma using individual Exiqon QPCR primers.

The sample IDs were listed on the X-axis and the miRNA concentrations were displayed on the Y-axis (in 40-Ct value). The miRNA IDs were indicated on top of the graph. Open bars represent plasma samples and the solid bars represent the corresponding serum samples. The values of standard derivation were obtained from three independent measurements. Two-way ANOVA was used to determine the statistical significance of the miRNA concentration differences between serum and plasma (p-values are shown in the figure).

https://doi.org/10.1371/journal.pone.0041561.g003

The coefficient of variation was used to determine the concentration variation of miRNAs measured by Exiqon panels. In plasma, miR-22 showed the highest concentration variation while miR-92a had the most stable concentration across samples. In serum, miR-29c and miR-720 had the highest and lowest concentration variations, respectively (Table 2). Like the Taqman miRNA measurement results, U6 and some SNORD RNAs were not consistently detected in both serum and plasma samples tested (Table S2).

The Results between Two QPCR Platforms Showed Low Consistency

Samples from 4 individuals were profiled with both Taqman and Exiqon miRNA QPCR panels. Based on the primer annotations, 358 miRNAs were in common between Taqman card A and Exiqon plate I and II. After combining the two datasets, 67 miRNAs could be detected in all 4 serum and plasma samples by both platforms. The average miRNA concentration of the 67 commonly detectable miRNAs showed 6.7 Ct values higher in Taqman than the Exiqon measurements. This was probably caused by the pre-amplification step implemented in the Taqman miRNA measurement protocol. Within each platform, both Taqman and Exiqon exhibited high correlations between serum and corresponding plasma samples (based on the 40-Ct values) (Figure S2A). However, the 67 commonly detectable miRNAs in both plasma and serum samples showed very low correlations between the two platforms (Figure S2B).

When comparing the measurements between platforms, there were several miRNAs that showed platform-associated amplification; for example, miR-107 showed a much better amplification with Exiqon compared to Taqman (Figure 4 and Tables S1 and S2).

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Figure 4. Certain miRNAs showing different measurement efficiency between measurement platforms.

The sample IDs and type of samples were listed on the X-axis. The miRNA concentrations were displayed on the Y-axis (in 40-Ct value). Gray bars represent Exiqon measurement results while solid bars represent the Taqman measurements from the same sample. The values of standard derivation were obtained from three independent measurements.

https://doi.org/10.1371/journal.pone.0041561.g004

Blood Cells Components Contained a Significant Amount of Detectable miRNAs

As expected, the blood cells had more detectable miRNA species, ranging from 280 to 477, compared to their serum or plasma counterparts (Tables 1 and Table S2). A significant number of these miRNAs (206 of them) were shared among all blood cell components. Either miR-223 or miR-451 was the most abundant miRNA in all RBC, WBC and platelet samples (Table S3). It is interesting to note that the concentration of miR-223 was relatively low in RBC compared to WBC and platelets. As in serum and plasma, U6 and SNORD RNAs were not detected in all samples, especially in platelets (Table S2). The degree of concentration variations of individual miRNAs in the WBC, RBC and platelet samples from different donors was also examined, and. the most variable and the most stable miRNA species were listed, respectively in Table 3.

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Table 3. The list of miRNAs with the most and least concentration variations in different blood cell samples and measurement platforms.

https://doi.org/10.1371/journal.pone.0041561.t003

A Number of miRNAs are Presented in Specific Blood Components

Of the 742 miRNAs in Exiqon panels, 178 were never detected in any of the samples tested including serum, plasma and their corresponding blood cell components. There were 206 miRNA species that can be detected in all blood cell components (WBC, RBC and Platelets) and 80 were in all samples tested (WBC, RBC, Platelets, serum and plasma). Based on our criteria, there were 26 miRNAs can only be seen in RBC samples and 1 miRNA unique to WBC (miR-24-5p) (Tables S2 and S4).

Discussion

There is a more than two-fold difference in the number of detectable miRNA species between the lowest (123 detectable miRNA in serum or plasma sample from 11-39691 with Exiqon panel) and highest (296 detectable miRNA in serum sample from ID-5 with Exiqon panel) number among serum and plasma samples tested (Table 1). However, no correlation between the number of detected miRNAs and the concentration of RNAs obtained was observed (Table 1). Therefore, the common practice of using similar amounts of RNAs might not be the best approach for circulating miRNA measurements. The difference in the number of detectable miRNA in the samples may have some physiological implications. However, it is difficult to interpret the significance of this difference without more detailed clinical information about the normal donors.

For miRNA measurement, data normalization is still a challenge, especially for circulating miRNA. Several small RNA species, such as U6 and SNORD RNAs have been used in miRNA data normalization. However, they are either not detectable or have very high concentration variations across different samples in our study (Tables S1 and S2). This observation suggests that RNAs like U6 or SNORD might not be suitable for normalizing extracellular miRNA measurements.

The levels of tissue-specific miRNAs in circulation have been advanced as potential blood biomarkers for various pathologies in specific organs. For example, the liver-specific miR-122 in drug-induced liver injury [12], [13], the muscle-specific miR-133a and b in muscle injury [13] and heart-specific miR-208 and miR-499 in myocardial infarction [5], [14]. Most of these miRNAs are not routinely detectable in the normal serum or plasma samples used in this study (Table S1). This supports the possibility of using the levels of these organ-specific miRNAs in circulation as biomarkers for site-specific pathologies.

RNA Including miRNAs May be Released from Blood Cells into Serum During Coagulation Process

Since the serum and plasma were collected at the same time from the same individual, the higher RNA concentration in serum (in 10 out of 12 samples) (Table 1) suggests that additional RNA was released from cells during the coagulation process. Cell lysis, especially the highly abundant red blood cells, during the coagulation process is one of the plausible explanations for this RNA concentration difference between serum and plasma. However, the concentrations of some of the highly abundant miRNA species in blood cell components such as, miR-150 in WBCs, miR-16 in RBCs and miR-126 in platelets were almost the same between serum and plasma (Table S2). In addition, the miRNA concentration difference between serum and plasma showed some associations with miRNA spectrum in platelets and WBCs, instead of the most abundant cell population, RBCs, in the blood (Figure S3).

This RNA concentration difference between serum and plasma is consistent with the idea of RNA/miRNA ‘trafficking” between cellular compartments and the extracellular environment [7], [15][21]. During the coagulation process, blood cells are exposed to a “stressful environment” which may “stimulate” the release of certain miRNAs and other RNAs, as was observed when cells were exposed in vitro to serum-free conditions [7]. In addition, the platelets also contained significant amounts of RNA (Table 1) [22] which might also be released into the serum during the coagulation process.

The difference of molecular composition between serum and plasma is well documented [23][27]. For example, the coagulation process increases sample-to-sample variations on the observed proteome which makes data analysis and comparison difficult. Our miRNA study yields a similar conclusion and suggests that plasma may be the sample of choice in studying circulating miRNA, since RNA released during the coagulation process may change the true repertoire of circulating miRNA. When using archived samples in circulating miRNA studies, special attention must be given to this difference, since the majority of the archived samples are stored as serum.

The Concentration for Some miRNAs may be Affected by Gender and the Measurement Platform

Gender-associated molecular differences have been reported in serum and platelet proteomes recently [28][30]. In addition to the concentration differences of some miRNAs between serum and plasma, a number of miRNAs showed concentration differences between genders. For example, miR-130b and miR-18b have slightly higher concentrations in male serum samples measured by Taqman platform (Table S1). This gender-associated circulating miRNA concentration difference has also been observed recently [31]. Even though the biological implications of these differences are yet to be determined, we cannot exclude the possibility that they are involved in some gender-associated functions.

The poor agreement among different miRNA measurement platforms has been reported earlier [32], [33]. The observation of low measurement consistency between the two commonly used QPCR miRNA measurement platforms and miRNA concentration differences between serum and plasma further illustrate the need for a commonly accepted miRNA measurement platform and sample preparation method, so that cross-study comparisons and independent data validations can be performed more effectively.

While there are numerous encouraging reports on the use of specific circulating miRNAs as biomarkers for various pathological conditions, it is important to understand factors that might affect the measurement of extracellular miRNA concentration and take these explicitly into account in diagnostic protocols. Our results suggest that circulating miRNA levels may be affected by various intrinsic and extrinsic factors including: the gender of the donor, the measurement platform used, and type of samples obtained. Even though some of these intrinsic factors may be associated with specific biological activities; however, with limited samples used in the study, it is not our intention to further interpret the results for its biological implications. Our findings simply illustrate the need for a larger and more comprehensive study with additional serum and plasma samples from better controlled donors in order to establish the boundaries for the use of circulating miRNA-based biomarkers. In addition, the standardization for sample preparation and miRNA measurement method is urgently needed to further develop circulating miRNA based biomarker.

Materials and Methods

Sample and RNA Isolation

Samples were obtained from either Biological Specialty Corporation (Biological Specialty Corporation, Colmar, PA) or Innovative Research (Innovative Research, Novi, MI). All samples were collected from healthy individuals with proper approvals by institutional review boards. The serum, plasma, and blood cell fractions were prepared according to standard protocols. In brief, serum was prepared by leaving the blood at room temperature for one hour before harvesting the supernatant. Plasma, RBC, WBC and platelets were prepared from 30 mLs of EDTA blood. The blood was initially centrifuged at 1000× g for 15 minutes to separate the plasma and blood cells. The supernatant was carefully removed and centrifuged again at 2500× g for 15 minutes to separate plasma and platelets. The platelet pellet was then resuspended in 7 ml of phosphate buffered saline (PBS, 137 mM NaCl, 2.7 mM KCl, 4.3 mM Na2HPO4, 1.4 mM KH2PO4, pH 7.5). The buffy coat from the initial spin was carefully collected and resuspended in RBC lysis buffer (10 mM KHCO3, 150 mM NH4Cl and 0.1 mM EDTA pH8.0) to remove RBC. The WBC containing solution was then spun at 1000× g for 10 minutes to collect WBC. The cell pellet was resuspended in 7 mL of PBS. The RBC fraction was taken directly from the original cell pellet. For serum or plasma, total RNA was extracted from 100 µl of the sample using the miRNeasy kit (Qiagen, Valencia, CA) as previously described [6], [12]. For RBC, WBC and platelets, 50 µl of the resuspended cell pellets were used in RNA extraction. The extracted RNA was assessed for quality and quantity with Agilent 2100 Bioanalyzer (Agilent, Santa Clara, CA) and NanoDrop 1000 spectrophotometer (Thermo Scientific, Wilmington, DE).

MicroRNA Measurement

For the Taqman assay (Applied Biosystems, Carlsbad, CA), 12 µl of isolated RNA was dried and resuspended in 3 µl of water. The cDNA was then generated using Megaplex RT Primer pools. Pre-amplification was performed using 2.5 µl cDNA according to the manufacturer’s protocol. The resulting samples were diluted and loaded onto the TaqMan® Array Human miRNA Panel. For Exiqon (Exiqon, Woburn, MA) miRNA profiling, 20 µl of RNA was used for cDNA synthesis using MiRCURY LNA™ Universal RT kit. The cDNA was then diluted and dispensed into the Exiqon Human miRNA panels. Since it is difficult to obtain accurate RNA concentrations we used the same volume of RNA isolated from serum and plasma samples in miRNA measurements. We only used card A in Taqman-based miRNA measurements, since it contained the majority of abundant miRNA species. The blood cell fractions were profiled with Exiqon miRNA panels only. QPCR was conducted with a 7900HT fast real-time PCR system (Applied Biosystems, Foster City, CA). Amplification results were analyzed with SDS 2.3 (Applied Biosystems, Foster City, CA). The amplification curves were individually inspected and miRNAs with abnormal amplification patterns or Ct values greater than 35 were removed from analysis. The complete Taqman and Exiqon QPCR miRNA profiling results are provided in Tables S1 and S2.

Supporting Information

Figure S1.

The Bioanalyzer electropherogram converted gel like image of RNA isolated from different sample types. The sample types are indicated on the top and the position of 18S and 28S RNAs are labeled by arrows.

https://doi.org/10.1371/journal.pone.0041561.s001

(TIF)

Figure S2.

Comparing the similarity of miRNA spectrum between serum and plasma. Scatter plots were used to demonstrate the similarity of miRNA concentrations between serum and plasma within the same measurement platform (A). The platform was indicated on top of the figure. Different platforms gave low correlation on concentration measurement (B) within either serum or plasma samples. The sample type was labeled on top of the figure. The plots were based on the average concentrations of 67 commonly detectable miRNA species in both Taqman and Exiqon QPCR platforms

https://doi.org/10.1371/journal.pone.0041561.s002

(TIF)

Figure S3.

The miRNA concentration between serum and plasma showed some association with miRNA concentrations in platelets and WBC. Scatter plots were used to demonstrate the correlation of miRNA concentration difference between serum and plasma and difference between platelets and plasma (A), WBC and plasma (B), and RBC and plasma (C). The average miRNA concentration differences between serum and plasma were represented on the Y-axis while the average differences between blood cell components and plasma were on X-axis. The plots were based on the average concentrations of 67commonly detectable miRNAs in all the samples.

https://doi.org/10.1371/journal.pone.0041561.s003

(TIF)

Table S1.

The serum and plasma miRNA measured by Taqman cards.

https://doi.org/10.1371/journal.pone.0041561.s004

(XLS)

Table S2.

The serum and plasma miRNA measured by Exiqon miRNA panels.

https://doi.org/10.1371/journal.pone.0041561.s005

(XLS)

Table S3.

The list of top 5 most abundatn miRNAs in different samples.

https://doi.org/10.1371/journal.pone.0041561.s006

(XLS)

Table S4.

The list of miRNAs showing preferential expression pattern among different blood components.

https://doi.org/10.1371/journal.pone.0041561.s007

(XLS)

Acknowledgments

We thank David Huang for his technical help. We also thank critical comments and suggestions from Drs. Richard Gelinas and Alton Etheridge.

Author Contributions

Conceived and designed the experiments: KW DJG. Performed the experiments: YY SM DB. Analyzed the data: JHC. Wrote the paper: KW DJG.

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