Abstract
Epilepsy frequently develops as a result of brain insult; however, there are no tools allowing to predict which patients suffering from trauma will eventually develop epilepsy. microRNAs are interesting candidates for biomarkers, as several of them have been described to change their levels in the brains, and in the plasma of epileptic subjects. This study was conducted to evaluate the usefulness of plasma miRNAs as epileptogenesis/epilepsy biomarkers. In our studies, we used a rat model of temporal lobe epilepsy. An epileptogenic insult was status epilepticus evoked by stimulation of the left lateral nucleus of the amygdala. Next, animals were continuously video and EEG monitored for 3 months. Blood was collected at 14, 30, 60, and 90 days after stimulation. Blood plasma was separated and miRNA levels were analyzed. We compared miRNA levels between sham-operated and stimulated animals, and between animals with high and low numbers of seizures. We propose three miRNAs that could be biomarkers of epilepsy: miR-671, miR-9a-3p and miR-7a-5p. According to us, miR-206-5p is a potential biomarker of epileptogenesis, and miR-221-3p is a potential biomarker of epilepsy severity. We think that these five miRNAs can be considered in the future as potential treatment targets.
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Introduction
Epilepsy is one of the most common neurological disorders, affecting approximately 50 million people worldwide1. Temporal lobe epilepsy (TLE) is the most common focal intractable seizure disorder in adults2. Although electroencephalography (EEG) is the gold standard of epilepsy diagnostics, it is limited to special epilepsy monitoring units (UMUs), where continuous EEG recording is available3. Additionally, brain imaging is not a sufficient tool for epilepsy prognosis. This is why there is a great need for the identification of molecular epilepsy biomarkers that could become easy, affordable, and, most importantly, noninvasive diagnostic tools3. Of those, particularly interesting can be biomarkers found in body fluids4.
Molecular biomarkers are particularly attractive because they offer the possibility of rapid, simple, and inexpensive bedside tests where a set of one or more molecules are measured in a convenient biofluid, such as blood3,5. Various circulating molecules have been investigated as potential epilepsy biomarkers. Among them are S100β (S100 calcium binding protein B), HMGB1 (high mobility group box 1), neuron-specific enolase, ghrelin and des-acyl ghrelin and inflammatory cytokines3,6,7,8,9,10,11,12. However, many of them suffer from a lack of specificity for a single brain disorder or present technical challenges.
An emerging class of potential biomarkers for neurological diseases is microRNAs (miRNAs)13. miRNAs are short noncoding RNAs (20–24 bp) that function via sequence-specific binding to the 3’-untranslated regions (UTRs) of target mRNAs. MicroRNAs come from endogenous transcripts that form local hairpin structures, which are processed such that a single miRNA molecule accumulates from one arm of a hairpin precursor molecule14. It is estimated that a single miRNA can regulate hundreds of genes, which makes them one of the most powerful regulators of gene expression15. miRNAs are widely expressed in the brain, both in neuronal and glial cells16,17. This makes miRNAs great targets for the exploration of diagnostic and therapeutic strategies.
The last decade has brought multiple reports of miRNA dysregulation in the brains of epileptic patients and in different epilepsy animal models18,19,20,21,22,23,24. Several studies also prove that manipulating specific miRNAs can affect seizure thresholds in animals25,26.
The first animal study to examine the effects of seizures on miRNA levels in blood appeared in 201027, and in 2015, the first clinical studies were published on blood-based miRNAs for the diagnosis of epilepsy28,29. Recent studies indicate that circulating miRNAs might also be used to help determine drug resistance in patients with TLE23.
Despite some information regarding miRNA changes in the plasma of animals in epilepsy models, we are still missing detailed information describing the long-term course of changes during epileptogenesis and epilepsy. This information may point to potential diagnostic biomarkers for epilepsy and targets for intervention during epileptogenesis. Therefore, we designed a complex study in which we measured the levels of miRNA in the plasma of rats at 14, 30, 60 and 90 days following the induction of epilepsy by status epilepticus (SE) evoked by electrical stimulation of the amygdala. We analyzed miRNA signatures in plasma depending only on time from epilepsy induction but also in relation to the stage of epilepsy development (presymptomatic vs symptomatic phase) and epilepsy phenotype in epileptic animals (low vs. high seizure number). We selected five miRNAs that could be potential biomarkers of epileptogenesis (miR-671, miR-9a-3p, miR-7a-5p), epilepsy (miR-206-5p), and epilepsy severity (miR-221-3p).
Methods
Animal surgery and status epilepticus induction
All animal procedures were approved by the Ist Local Ethical Committee on Animal Research in Warsaw (permit no. 483/2013, and 737/2015) and conducted in accordance with the guidelines established by The European Council Directives 2010/63/EU and ARRIVE guidelines. Adult male Sprague‒Dawley rats (270–320 g) were housed under controlled conditions (24 °C, humidity 50–60%, 12/12 h light–dark cycle) with food and water available ad libitum. Animals were housed in pairs. The environment was enriched by using various toys and snacks, which were changed every week. Experimentators spent extensive time with all the animals outside the experimental setting to decrease the stress of animals. Rats were subjected to regular handling every other day for 10 min. Additionally, to decrease the stress of rats in the experiment, they were first trained to being transported between specific rooms and used to handling during all the procedures.
The amygdala stimulation model of temporal lobe epilepsy was used in this study as previously described with some modifications30. Surgery was performed under isoflurane anesthesia (2–2.5% in 100% O2), followed by the injection of butorphanol (Butomidor, Richter Pharma AG, Wells, Austria; 0.5 mg/kg i.p.) for analgesia. A stimulating and recording bipolar wire electrode (Plastic One Inc., Roanoke, VA, # E363-3-2 WT-SPC) was implanted into the left lateral nucleus of the amygdala 3.6 mm posterior and 5.0 mm lateral to bregma and 6.5 mm ventral to the surface of the brain. A stainless steel screw electrode (Plastic One Inc., Roanoke, VA, #E363/20) was implanted contralaterally into the skull over the right frontal cortex (3.0 mm anterior and 2.0 mm lateral to bregma) as a surface EEG recording electrode. Two stainless steel screw electrodes were placed bilaterally over the cerebellum (10.0 mm posterior and 2.0 mm lateral to bregma) as grounding and reference electrodes. The contacts of all electrodes were placed in a multichannel electrode pedestal (Plastic One Inc., Roanoke, VA, #MS363), which was attached to the skull with dental acrylate (Duracryl Plus). After two weeks of recovery, animals were electrically stimulated via the intra-amygdala electrode to evoke SE. Stimulation consisted of a 100-ms train of 1-ms biphasic square-wave pulses (400 μA peak to peak) delivered at 60 Hz every 0.5 s for 30 min. If the animal did not enter SE, stimulation was continued for an additional 10 min. The SE was stopped 1 h after stimulation via an intraperitoneal injection of diazepam (20 mg/kg). If the first dose of diazepam did not suppress SE, the animal received subsequent doses of diazepam at 5 mg/kg. All stimulated animals were moved just after the stimulation to VIDEO-EEG monitoring units to confirm development of self-sustained status epilepticus and later to confirm the effect of i.p. diazepam injection to stop status epilepticus. Time-matched control animals had electrodes implanted but did not receive electrical stimulation. Due to extensive animal welfare improvements, the survival rate in our experimental model was very good and in all experimental cohorts one animal passed away during surgery and one after diazepam injection.
Rats were monitored with VIDEO-EEG (Comet EEG, Grass Technologies, West Warwick, RI; Panasonic WV-CP480) continuously from the moment of stimulation until the end of week 5 of the experiment (1st vEEG), from week 11 to week 16 (2nd vEEG) and starting at week 27 until the end of the experiment (3rd vEEG). Spontaneous seizures were identified from EEG recordings by browsing the EEG manually on the computer screen. An electrographic seizure was defined as a high-frequency (> 8 Hz), high-amplitude (> 2 × baseline) discharge lasting for at least 5 s. The latency to the first spontaneous seizure, number and frequency of seizures, and number of epileptic animals in each group were evaluated.
The discovery cohort was prepared in two rounds. The first group of animals consisted of 6 control and 8 stimulated rats, and the second group consisted of 5 control and 7 stimulated animals. The validation cohort was prepared in four rounds, consisting of 2 control and 3 stimulated rats each. Experimental conditions were identical to those in the discovery cohorts of animals. In total, the discovery cohort consisted of 11 control and 15 stimulated animals, and the validation cohort consisted of 8 controls and 12 stimulated rats. The experimental design is presented in Fig. 1.
Blood collection and plasma separation
Blood was drawn from restrained rats (#RSTR553N, Kent Scientific) at 14 days, 30 days, 60 days, and 90 days after SE. The blood was always drawn between 9 and 11 am. Every time the blood was drown interchangeably from control and stimulated group, and animals were chosen at a random order. Blood samples were collected from the tail vein in tubes coated with 1 mg \({K}_{2}\) EDTA (#363706, BD Vacutainer, USA). Within minutes after the blood draw, the blood was centrifuged at 1500 rpm for 5 min at + 4 °C. Plasma was later transferred to a new tube, aliquoted into 50 µl portions, snap frozen using dry ice, and stored at − 80 °C until use.
miRNA isolation and profiling
miRNA was isolated from 50 µl of plasma using the miRCURY RNA isolation kit—Biofluids (#300112, Woburn, MA, Exiqon). The whole miRNA isolation procedure was performed as described in the producer’s manual (v. 1.7). Additionally, 1 µg of MS2 RNA (#10165948001, Mannheim, Germany, Roche Diagnostics GmbH) was used to increase miRNA yield during RNA isolation. Spike-in controls (miRCURY LNA Universal R microRNA PCR, RNA Spike-in Kit, #203203, Exiqon) were used as the internal microarray control. At the end of the procedure, RNA was eluted in 50 µl of RNAse-free water, aliquoted, and stored at − 80 °C.
miRNA levels were profiled using miRNA 4.1 Array Strip (#902404, Santa Clara, CA, Affymetrix). The procedure was performed according to the manufacturer’s recommendations. Eight microliters of RNA was used to perform a poly-A-tailing reaction (AF-902134 GA HWS Kit for miRNA Arrays, Affymetrix). Hybridization was performed for 20 h at + 48 °C (AF-900454 GeneChip Hybridization Control Kit, Affymetrix). It was followed by the wash and stain protocol (AF-901910 FlashTagTM Biotin HSR RNA Labeling Kit, Affymetrix). The whole procedure was performed using the GeneAtlas™ instrument from Affymetrix (#00-0393).
The data discussed in this publication have been deposited in NCBI's Gene Expression Omnibus31 and are accessible through GEO Series accession number GSE241756 (https://www.ncbi.nlm.nih.gov/geo/query/acc.cgi?acc=GSE241756).
Real-time PCR
Alterations in the levels of selected miRNAs detected with microarrays were validated using the TaqMan system from Applied Biosystems by Life Technologies. In the discovery cohort, the same miRNA extracts were used for microarray experiments. cDNA synthesis was performed using a TaqMan MicroRNA Reverse Transcription Kit (#4366597, Vilnius, LT, Applied Biosystems by Life Technologies) and a nexus gradient Mastercycler (#6331, Eppendorf AG).
The PCR was performed using TaqMan Fast Universal PCR Master Mix (#4367846, Foster City, CA, Applied Biosystems by Life Technologies) and MicroAmp Fast Optical 96-Well reaction plates (#4346906, Applied Biosystems by Life Technologies) in a StepOnePlus System (Thermo Fisher Scientific). The primers used were as follows: miR-344a-5p: 4440886_463878_mat; miR-671: 4427975_002322; miR-3557-5p: 4440886_462825_mat; miR-1843b-5p: 4440886_476825_mat; miR-325-3p: 4427975_002510; miR-341: 4440886_461925_mat; miR-9a-3p = miR-9*: 4427975_002231; miR-3549: 4440886_465095_mat; miR-337-3p: 4440886_000193; miR-7a-5p: 4427975_000268; miR-218a-2-3p: 4427975_002294; miR-3593-5p: 4440886_462108_mat; miR-3556a: 4440886_463403_mat; miR-194-3p = miR-194*: 4427975_463169_mat; miR-206-5p = miR-206*: 4440886_463430_mat; miR-142-3p: 4427975_000464; miR-221-3p: 4427975_000524; miR-301a-3p: 4427975_000528. Data were analyzed using StepOne Software v2.3. The comparative Ct method (ΔΔCt method) was selected for analysis and performed according to ThermoFisher recommendations. As a reference, we used miRNA-301a-3p, which was selected as the most stable in our experiment, using the NormFinder algorithm32.
Data analysis
Data analysis of the miRNA 4.1 Array Strips identifying up- and downregulated miRNAs was performed with RStudio (R v. 3.3.2) using Bioconductor33, oligo and limma packages. The microarrays were normalized with the Robust Multiarray Average (RMA) algorithm (oligo package version 1.22.0)34. For the expression analysis, the calculated p values were based on moderated t-statistics. Furthermore, the Benjamini and Hochberg multiple testing adjustment method was applied to the p values (FDR—false discovery rate). One-way ANOVA was used to establish miRNAs with differential levels between groups.
The correlation, cluster, and principal component analyses were performed in RStudio (R version 3.3.2)35. Principal component analysis (PCA) was performed on microarray probes and illustrated on PCA plots (splom) using the tidyverse and scatterplot3d packages. For the heatmap clustering of miRNAs with significantly different expression (p < 0.05) between all epileptic and sham-operated control animals, miRNAs were ordered with the clustering complete-linkage method and the Pearson correlation distance measure. The heatmap diagrams were generated with the gplots package. The Pearson correlation test was used to analyze the correlations between miRNAs with significantly different expression levels (p < 0.05) between stimulated and sham-operated control animals. The fuzzy c-means algorithm implemented in the Mfuzz package36 was used to perform clusterization on all probes.
Statistics
The statistical analysis of Real-time PCR data was performed using Graph Pad Prism (v.8, GraphPad Software, USA). One-way ANOVA with the Bonferroni correction was used. The statistical significance was determined as follows: p < 0.05 “*”, p < 0.01, “**”, p < 0.001 “***”.
Ethics approval and consent to participate
All animal procedures were approved by the Ist Local Ethical Committee on Animal Research in Warsaw (permit no. 483/2013, and 737/2015) and conducted in accordance with the guidelines established by The European Council Directives 2010/63/EU.
Results
Differences between sham and stimulated animals
We evaluated the expression of miRNA in the plasma of experimental animals consecutively at 14, 30, 60, and 90 days following amygdala stimulation-induced SE and time-matched sham controls. The experiment was carried out according to the experimental design presented in Fig. 1.
We identified statistically significant changes in the levels of several miRNAs at the p < 0.05 cutoff. At 14 days, there were 90 miRNAs, at 30 days 47 miRNAs, at 60 days 81 miRNAs, and at 90 days 63 miRNAs with altered levels. Heatmaps (Fig. 2A) revealed different signatures between control and stimulated animals. Principal component analysis (PCA) separated control and stimulated animals at all tested time points (Fig. 2B).
We did not identify miRNAs that would change their levels at all tested time points, and only a few had altered levels at more than one time point (Fig. 2C). This indicates that most alterations in miRNA levels are transient.
To visualize alterations in miRNA levels over time, we performed cluster analysis using the Mfuzz algorithm (Fig. 2D). We identified several patterns of changes in ensembles of miRNAs over time, both in sham-operated and stimulated animals. Interestingly, we observed that some miRNA ensembles fluctuate in control animals (e.g., Fig. 2D—for example, clusters 1, 6, and 9). Patterns of miRNA levels over time are altered in stimulated animals (e.g., Fig. 2D—clusters 2, 5, and 7). This proves that miRNA levels change over time in the plasma of healthy animals and that epilepsy significantly affects their levels.
Since we identified a large number of miRNAs with altered levels, we concentrated on miRNAs with significantly changed levels in both experimental groups of the discovery cohort. We used a p < 0.05 cutoff, and in total, we discovered 13 miRNAs at all tested time points. We identified 5 miRNAs at 14 days post-SE. The upregulated genes were miR-344a-5p (logFC = 0.34, p = 0029, AUC = 0.6783), miR-671 (logFC = 0.28, p = 0.0008, AUC = 0.7902), miR-1843b (logFC = 0.39, p = 0036, AUC = 0.8182), and miR-325-3p (logFC = 0.24, p = 0007, AUC = 0.8042), and the downregulated gene was miR-3557-5p (logFC = − 0.52, p = 0.152, AUC = 0.7522). At 30 days post-SE, only one miRNA was changed. MiR-341 (logFC = 0.34, p = 0.0001, AUC = 0.9371) was upregulated. At 60 days, all selected miRNAs were downregulated: miR-9a-3p (logFC = -0.16, p = 0.0070, AUC = 0.8308), miR-3549 (logFC = − 0.61, p = 0.0002, AUC = 0.8615), and miR-337-3p (logFC = − 0.34, p = 0.0052, AUC = 0.6846). At the last tested time point (90 days post SE), 4 miRNAs were downregulated: miR-7a-5p (logFC = − 0.25, p = 0.0014, AUC = 0.8926), miR-218a-2-3p (logFC = − 0.21, p = 0.0098, AUC = 0.8264), miR-3593-5p (logFC = − 0.37, p = 0.0003, AUC = 0.9256) and miR-3556a (logFC = − 0.53, p = 0.0001, AUC = 0.9752). We performed ROC analysis to assess the sensitivity and specificity of each miRNA change. Values of AUC (area under the curve) close to 1 indicate that all selected miRNAs are potentially good biomarkers of epilepsy.
To validate our results, we performed a series of real-time PCR experiments using the TaqMan system from Thermo Fisher Scientific (Fig. 3A) using plasma from both discovery and validation cohorts. Out of the 13 previously selected miRNAs, we found 3 miRNAs: miR-671 from 14 days post-SE, miR-9a-3p from 60 days post-SE, and miR-7a-5p from 90 days post-SE, which gave us similar, significant results in all 3 independent tests: microarrays, real-time PCR on the experimental cohort, and real-time PCR on the validation cohort. ROC analysis for these 3 miRNAs showed good sensitivity and specificity (AUC = 0.79 [miR-671], 0.85 [miR-9a-3p], and 0.89 [miR-7a-5p]) (Fig. 3B) Taking all these data into consideration, we propose that miR-671, miR-9a-3p and miR-7a-5p are potentially good biomarkers differentiating sham from stimulated animals.
Differences between epileptic and nonepileptic stimulated animals
All stimulated animals developed epilepsy, diagnosed by the presence of spontaneous seizures at times following stimulation. However, the latency to the first spontaneous seizure differed between animals. This provided an opportunity to study differences in miRNA levels in epileptic vs. nonepileptic animals. At 14 days post SE, 7 animals had spontaneous seizures, whereas 6 animals were in the presymptomatic phase. At 30 days post-SE, 9 animals developed epilepsy, and 4 animals did not. At the 60- and 90-day time points, all stimulated animals were diagnosed with epilepsy. We analyzed differences in miRNA levels in sham animals vs. epileptic animals vs. presymptomatic animals.
At 14 days post SE, 76 miRNAs differed between epileptic and presymptomatic animals (Fig. 4A), while at 30 days post SE, there was a difference in the levels of 68 miRNAs between epileptic and presymptomatic animals (Fig. 4A) (p < 0.05 cut off).
PCA clearly separated sham, epileptic and presymptomatic animals (Fig. 4B). Epileptic and presymptomatic animals were localized in opposite places in the 3D space in relation to sham animals. This suggests that the presymptomatic phase is not just a transitional phase before epilepsy diagnosis but also has specific characteristics.
We also compared the patterns of miRNAs differentiating between epileptic and presymptomatic animals over time in sham vs. epileptic vs. presymptomatic animals using the Mfuzz clustering algorithm (Fig. 4C). We observed that the levels of these miRNAs are relatively stable in sham animals, whereas in epileptic and presymptomatic animals, there are profound changes in levels over time. Interestingly, many of these changes occur in opposite directions in epileptic animals compared with presymptomatic animals. This is strong evidence of wide differences between the presymptomatic and symptomatic phases in epilepsy progression. It also indicates that in presymptomatic animals, there are several specific molecular processes being activated not only in the brain but also in the plasma of animals.
As a further step of our analysis, we selected miR-206-5p and miR-194-3p as miRNAs, whose levels changed similarly at both analyzed time points (Fig. 4D). Both miRNAs presented increased presymptomatic levels compared to epileptic animals at 14 days post-SE (Fig. 4E). At 30 days, miR-206-5p expression in presymptomatic animals was still elevated, whereas miR-194-3p was decreased. We later validated results obtained by microarrays using real-time PCR (TaqMan system). Since the detected level of miR-194-3p was extremely low, we thought it did not fulfill the requirement for being a good candidate biomarker. Thus, for further analysis, we focused solely on miR-206-5p. Real-time PCR for miR-206-5p confirmed our previous observation that its expression is increased at 30 days post-SE in presymptomatic animals (Fig. 4F). ROC analysis (Fig. 4G) assessed miR-206-5p sensitivity and specificity as very good, with AUC = 0.8. This indicates that miR-206-5p is a good candidate biomarker for preclinical studies differentiating between the symptomatic and presymptomatic phases of epilepsy.
Differences between epileptic animals with low vs. high numbers of seizures
Epileptic animals in our experiment had variable seizure numbers; therefore, we could divide epileptic animals into two groups according to the median number of seizures (median 473.9). As a result, we obtained a group of epileptic animals with low (median = 95.0) and high (median = 692.8) numbers of seizures during 8 months after SE (Fig. 5A). We found a number of miRNAs differentiating between animals with low vs. high seizure numbers at all time points: 132 miRNAs at 14 days, 34 miRNAs at 30 days, 48 miRNAs at 60 days and 57 at 90 days post-SE (p < 0.05 cut off). Heatmaps for each time point show different signatures for plasma samples from animals with low and high numbers of seizures (Fig. 5C).
Interestingly, an increase or decrease in the levels of given miRNAs was usually transient. Comparison of miRNAs significantly changing levels at different time points revealed no miRNAs that would have changed expression at all tested time points (Fig. 5B). We only observed a single miRNA changing its level at 2 time points.
Mfuzz clustering analysis revealed very interesting patterns between control animals and animals with high and low numbers of seizures (Fig. 5D). What is clearly visible in the expression pattern over time is that in significantly changing miRNAs, the difference between high and low animals is usually the opposite. For example, in cluster 2, the level of miRNAs decreased over time in animals with a high number of seizures, whereas it increased over time in animals with a low number of seizures (Fig. 5D).
We selected 3 miRNAs for more detailed analysis. We found that miR-221-3p is the one that best distinguishes between animals with high and low numbers of seizures (Fig. 5E). The difference in real-time PCR analysis from the discovery cohort (CTRL n = 11, and SE n = 15) was not significant; however, it showed a strong tendency toward the same changes as observed in microarrays. We ran PCR on the same RNA as the microarrays. Analysis by real-time PCR in a validation cohort with a higher number of animals revealed a significant change in miRNA-221-3p levels. Taken together, these results convinced us that miR-221-3p is a good biomarker that can distinguish early in epilepsy development between animals with high and low numbers of seizures.
Discussion
In this study, we present a set of miRNAs whose signatures induced by status epilepticus in plasma change over long periods. We identified miRNAs that can serve as putative biomarkers of an asymptomatic phase of epilepsy development and miRNAs that allow assessment of epilepsy severity by differentiating between animals with low vs. high seizure numbers. All the identified miRNAs can be potentially useful for preclinical studies.
Molecular biomarkers, such as miRNAs, which could be reliably detected in easily obtainable biofluids, could mean a breakthrough in epilepsy diagnosis8,19,21,23,28,29,37,38,39,40. Plasma is a good choice for diagnostic biofluids. It is easily obtainable, contrary to cerebrospinal fluid, and allows for avoiding clotting events, which can occur in serum and can create strong variability in miRNA profiles41.
Our study involved a dual-platform approach to discover TLE biomarkers of different phases of epilepsy development. The discovery phase of our experiments led to the identification of several miRNAs that changed levels between sham animals and animals at different stages of epilepsy development with different epilepsy phenotypes. These results were validated using TaqMan Real-time PCR as an alternative method using an additional animal cohort. This approach allowed us to propose three miRNAs whose levels change significantly after status epilepticus (miR-671, miR-9a-3p, miR-7a-5p), one as a biomarker of the presymptomatic phase (miR-206-5p) and one as a biomarker of epilepsy severity (miR-221-3p). This is the first such detailed, long-term study of circulating miRNA expression profiles in animal models of TLE.
To date, only a few papers have been published presenting changes in miRNA levels in blood or plasma after seizures and/or epilepsy induction. They present changes in miRNA levels 24 h after kainate injection27 or lithium and pilocarpine injection42. They identified several miRNAs with changed levels both in the brain and the blood. This led to the idea that there may be a “leakage” of miRNAs to the blood from the brain after seizures. Interestingly, similar miRNA changes were observed after seizures and after ischemia and intracerebral hemorrhage. This may indicate that these miRNAs may be markers of brain injury of different etiologies27.
Gorter et al. published the results of their study in which they checked the expression of miRNAs in the hippocampi of animals after SE induced by electrical stimulation of the hippocampus43. They performed a timeline analysis of changes during epileptogenesis and after epilepsy development at 1, 7, and 30 days post-SE. They selected 3 upregulated miRNAs, miR-146a-5p, miR-21-5p, and miR-142-5p, and their pattern of expression in plasma was similar to that observed in the brain. This study confirmed that the same miRNAs can be deregulated in the brain as in biofluids and can serve as biomarkers of epileptogenesis and epilepsy.
Roncon et al. examined miRNA expression profiles in the plasma of rats in the lithium-pilocarpine model at early and late latency phases and in a chronic phase of epilepsy using microarrays and discovered an increase in miR-9a-3p levels as a potential early epileptogenesis biomarker20.
Raoof et al. performed RNA sequencing from plasma samples of TLE patients, which included psychogenic nonepileptic seizures (PNES), 24 h after they experienced a seizure44. After profiling and validation, they identified miR-27a-3p, miR-328-3p, and miR-654-3p as potential symptomatic epilepsy biomarkers. The same miRNAs were detected in the plasma of animals that underwent intraamygdala injection of kainic acid.
Brennan et al. performed a study of miRNA profiling in plasma in three different animal models: kainate, pilocarpine, and perforant pathway stimulation45. The authors identified a set of 5 miRNAs that changed similarly in all tested models: miR-93-5p, miR-142-5p, miR-182-5p, miR-199a-3p and miR-574-3p. Validation studies found that miR-93-5p, miR-199a-3p, and miR-574-3p were also dysregulated in plasma from patients with intractable temporal lobe epilepsy, proving that similar changes in miRNA levels detected in animal models can be detected in human samples.
We identified three miRNAs regulated in plasma by SE: miR-671 upregulated at 14 days post-SE, miR-9a-3p downregulated at 60 days post-SE, and miR-7a-5p downregulated at 90 days post-SE. MiR-671 was previously found to be upregulated in the plasma of patients suffering from traumatic brain injury, which can induce epilepsy in animals and human patients46,47. Interestingly, miR-671 indirectly regulates miR-7 activity by targeting and reducing circular RNA ciRS-7 levels in HeLa cells48.
An increase in miR-9a-3p levels in the plasma of pilocarpine-induced epileptic rats was previously proposed as a biomarker of the early stages of epileptogenesis20. Roncon et al. showed an increase in miR-9a-3p levels only in the early phases of epileptogenesis (4 days post-SE), and at 8 days post-SE, it had already dropped, whereas in our study, the first time point tested was 14 days after SE, where we also did not detect a significant difference in miR-9a-3p levels20. In our model of electric amygdala stimulation, miR-9a-3p expression was downregulated at the chronic phase of epilepsy at 60 days post-SE. Roncon et al. did not detect an increase in miR-9a-3p at 60 days post-SE, as we did, and they did not check later time points. It is possible that the timeline of miR-9a-3p level increase is different in various animal epilepsy models and requires more detailed testing to fully understand how miR-9a-3p levels change over time. Nevertheless, this miRNA is of interest in future studies of epileptogenesis/epilepsy biomarkers. Interestingly, increased miR-9a-3p levels in human plasma samples were implicated in Alzheimer’s disease, frontotemporal dementia and Parkinson’s disease49. This may suggest that miR-9a-3p (miR-9*) can be considered a marker of general neurological damage. miR-7a-5p has been shown to be upregulated in extracellular vesicles from the brain in an animal model of traumatic brain injury50. In our previous study, we found that its level is decreased in the dentate gyrus of epileptic rats19 at the same time point. It can be concluded that all 3 miRNAs have potential as brain damage biomarkers.
In the next step, we focused on differentiating animals in presymptomatic and symptomatic phases of epilepsy. We identified 2 miRNAs, miR-206-5p and miR-194-3p, which were elevated in nonepileptic animals both at 14 and 30 days post-SE when compared to epileptic animals. Due to a low level of miR-194-3p expression, we decided that miR-194-3p is not a suitable candidate. Another candidate, miR-206, plays a role in cardiomyocyte function by regulating connexin 43 (Jin et al. 2018). miR-206 also showed increased levels in the serum of mild cognitive impairment (MCI) patients51. miR-206-3p expression was significantly upregulated in the hippocampus and cortex of APP/PS1 mice in the pathology of Alzheimer’s disease and influenced the expression of BDNF (brain-derived neurotrophic actor)52. We propose that miR-206-5p is a potentially good candidate biomarker of the asymptomatic phase of epilepsy since its levels rise in the plasma of stimulated animals that have not yet developed epilepsy.
We would like to stress that when analyzing miRNA level changes in plasma after SE, it is clear that epileptogenesis (asymptomatic phase) is a process that can be clearly distinguished from the symptomatic phase of epilepsy. This finding is in agreement with the results we obtained when analyzing brain miRNA levels in the dentate gyrus after SE induction19. Similar observations were evident in studies of circulating RNA levels in the plasma of pilocarpine-injected animals20 and in the plasma of animals after SE induced by electrical stimulation of the hippocampus43. This observation is direct proof that epileptogenesis can be identified by ongoing miRNA level changes and that they are good candidates for epileptogenesis biomarkers.
We found that the level of miR-221-3p is higher in animals with low seizure numbers, and therefore, it is a potential biomarker of epilepsy severity. Bencurova et al. showed that the level of miR221-3p was elevated in the rat hippocampus at the chronic stage in the pilocarpine model of epilepsy38. In agreement with our observations from plasma, miR-221-3p decreases in the cerebrospinal fluid and urine of children suffering from traumatic brain injury53 and is upregulated in the cerebrospinal fluid of ischemic stroke patients54. This means that miR-221-3p levels may depend on etiology and/or disease prognosis.
We performed biomarker selection using multiple animal groups and dual-platform selection. We think that the proper procedure of epilepsy biomarker identification should involve such a multilayered approach to allow for the selection of only those biomarkers that have the highest rate of change, are easy to detect and are reliably detected despite many differences that can be present in subsequent cohorts of animals. This observation is in agreement with human studies where miRNA profiling is performed. According to Raoof et al., using dual-platform and possibly dual-center approaches in miRNA profiling studies is crucial44. Only then will we be able to identify epilepsy biomarkers and potential targets for therapeutic intervention. Using single cohort experiments or pooled samples does not have strong diagnostic potential. Therefore, our experiments have an advantage over previously published studies searching for miRNAs in plasma in various epilepsy models as epilepsy biomarkers. Our study consisted of several experimental and validation animal groups. Additionally, the length of our study allowed us to examine various stages of asymptomatic and symptomatic phases of epilepsy in the animal model of temporal lobe epilepsy.
Conclusions
Our complex, long-term study with multiple discovery and validation animal groups, using two platforms to test the expression of miRNA, allowed the discovery of SE-induced, presymptomatic, and epilepsy severity-related biomarkers. Although the mechanistic role of these miRNAs is not determined, they can be very useful as biomarkers of disease stage or severity. Most importantly, they can be valuable tools in preclinical studies and allow assessment of the disease's development or progression.
Data availability
The data discussed in this publication have been deposited in NCBI's Gene Expression Omnibus31 and are accessible through GEO Series accession number GSE241756 (https://www.ncbi.nlm.nih.gov/geo/query/acc.cgi?acc=GSE241756).
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Acknowledgements
We would like to acknowledge Aleksandra Stepniak for her help with the plasma samples collection and occasional help with the animal care.
Funding
The project was supported by the granting agencies FP7-HEALTH project 602102 (EPITARGET) and Polish Ministry of Science and Education grant W19/7.PR/2014.
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Conceptualization: K.S. and K.L. Methodology: K.S., A.B., K.L. Investigation: K.S., K.N., M.O. Data curation and Formal Analysis: K.S. Visualization: K.S. Writing–original draft preparation: K.S. Writing—review and editing: K.S. and K.L. Supervision: K.L. Funding Acquisition: K.L. All authors have read and agreed to the published version of the manuscript.
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Szydlowska, K., Bot, A., Nizinska, K. et al. Circulating microRNAs from plasma as preclinical biomarkers of epileptogenesis and epilepsy. Sci Rep 14, 708 (2024). https://doi.org/10.1038/s41598-024-51357-4
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DOI: https://doi.org/10.1038/s41598-024-51357-4
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