Figure 4.4 Differential expression map of circulating miRNAs dysregulated after a specific heavy metal or mixed metal exposure across different body fluids. Circulating miRNAs dysregulated in different biofluids (blood, plasma, serum and urine) upon exposure to (A) arsenic (As), (B) cadmium (Cd), (C) chromium (Cr), (D) mercury (Hg), (E) lead (Pb), and (F) mixed metals (MM). Induced circulating miRNAs are represented in blue, suppressed or lower circulating miRNAs are represented in green, miRNAs that were not examined in a particular biofluid for specific metals are represented in white, and miRNAs that showed conflicting results in multiple studies within a biofluid are shown in purple.
Future Avenues of Research
Importantly, all circulating miRNAs associated with metal exposure are currently in stages of discovery and development and have not yet been validated; nor are they considered biomarkers. Biomarkers must be validated in accordance with well-established protocols that involve multiple independent qualitative and quantitative steps, before they can be employed for diagnosis or monitoring (Califf 2018). Consequently, there is a significant knowledge gap when it comes to identifying a circulating miRNA that can be used consistently or can be used as a unique biomarker for heavy metal exposure or for disease outcome(s) of such exposure. Therefore future studies should first find out whether there are differences between heavy metal exposures for the circulating miRNAs summarized in Figure 4.3. Furthermore, the assessment of these candidate biomarkers and of other circulating miRNAs should be validated in other fluids that do not rely on blood draw and contain high levels of miRNAs, for instance sweat, tears, saliva, semen, or breast milk (Barcelo et al. 2019; Karvinen et al. 2020; Rubio et al. 2018; Setti et al. 2020; Weber et al. 2010).
Other areas that need to be addressed are things such as limited sample sizes and the inclusion of geographically restricted populations. Both factors need to be taken into account when suggesting the use of a circulating miRNA as a putative biomarker. Ideally, future studies should be performed with these candidate circulating miRNAs across larger populations from numerous geographic regions. This approach will ultimately enable multiple stratifications across biological and socioeconomic parameters in order to investigate whether initial patterns discovered for circulating miRNAs are both consistent and associated with these additional factors.
Although causality is not a required criterion for a biomarker, it would be important and interesting to examine whether any of these dysregulated miRNAs plays a causal role in the etiology of any metal exposure-induced diseases. A few studies have been conducted in this direction. As consistent with human studies, miR-21 was increased in immortalized human keratinocytes (HaCaT) exposed to 500 nM arsenite for four weeks (Gonzalez et al. 2015) and in human umbilical vein endothelial cells (HUVEC) exposed to 20 μM arsenite for twenty-four hours (Li et al. 2012). A recent systematic review and meta-analysis suggests that arsenic-induced miR-21 expression suppresses phosphatase and tensin homolog (PTEN) and protein sprouty homolog 1 (Spry1) levels, leading to epithelial–mesenchymal transition (EMT) and malignant transformation (Liu et al. 2018). miR-21 is a well-conserved miRNA, frequently found upregulated in numerous types of cancer (Feng and Tsao 2016). Furthermore, in cadmium-exposed individuals, miR-21 was associated with renal dysfunction, characterized by increased excretion of the low molecular weight protein N-Acetyl-beta-(D)-glucosaminidase in urine (Lei et al. 2019). Thus it is important to consider circulating miR-21 as a potential biomarker for heavy metal exposure and to investigate its potential mechanistic role in heavy metal exposure-induced disease outcomes. Similarly, upregulation of miR-92a-3p and miR-486-5p after mercury exposure has been recapitulated in vitro by exposing HEK-293 and HUVEC human cell lines to mercuric chloride (Ding et al. 2017).
Techniques and Challenges for Identifying Circulating miRNAs
Although using circulating miRNA as biomarkers has its advantages, since this is a relatively non-invasive technique and also one that can in principle be used in the early diagnosis of diseases, miRNA profiling in biofluids is still in its infancy. Therefore it is necessary to highlight limitations that may lead to inconsistent findings. The identification of potential confounding factors will also help optimize the reproducibility of miRNA future biomarker studies used in metal toxicology.
Perhaps the biggest challenge to the successful identification of circulating biomarkers lies in the technical constraints on isolating and purifying the samples for analysis. Methods used by different groups to isolate miRNAs from blood vary greatly, which may contribute to reproducibility issues (Mariner et al. 2018). For instance, previous studies have shown that the differential expression analysis of circulating miRNA from plasma can be confounded by the presence of platelets, which require additional steps of centrifugation in order to accurately quantify differential circulating miRNA expression profiles (Cheng et al. 2013). However, one protocol to address this issue has already been developed (Mariner et al. 2018). Additionally, the type of RNA extraction protocol can vary from lab to lab. Traditional approaches to extracting RNA use phenol:chloroform steps to separate RNAs from proteins, then precipitation of RNA with alcohol and pelleting by centrifugation (Mariner et al. 2018). But the size and quantity of circulating miRNAs may make them difficult to pellet, and this leads to greater sample variability. Furthermore, commercialized kits that use column-based purification techniques such as RT-qPCR, next-generation sequencing, or microarray approaches may inhibit the most common downstream miRNA quantification as a result of the incomplete removal of denaturants.
Other challenges—for instance the normalization of data to a housekeeping circulating miRNA or other genes, low concentration of circulating miRNAs, and identification of acceptable ranges for certain circulating miRNAs in profiles of normal individuals—can contribute to data variability or impede meaningful interpretations (Cui et al. 2019). One study has addressed the effect of different normalization strategies to quantify the circulating miRNAs in human plasma and has found that miR-320d may be the most reliable endogenous circulating miRNA to use for normalization (Faraldi et al. 2019). Alternatively, others have used exogenous, synthetic miRNA mimic from C. elegans as normalization controls (Farina et al. 2014). Although according to some studies storage conditions do not seem to play a role in affecting the stability of circulating miRNAs, multiple freeze thaw cycles should be avoided in order to reduce the degradation of limited circulating miRNA species, and samples should kept at -80 C for long-term storage (Farina et al. 2014; Tiberio et al. 2015). Lastly, no studies to date have addressed the matter of a normal physiological range for circulating miRNAs. However, on the basis of individual variability in circulating miRNAs, these studies are needed before the use of circulating miRNAs as biomarkers in a clinical setting.
Acknowledgement
The authors were supported by the National Institute Of Environmental Health Sciences of the National Institutes of Health under Award Numbers R01ES027778, R21ES030334, P30ES030283, and T32ES011564. The content is solely the responsibility of the authors and does not necessarily represent the official views of the National Institutes of Health.