Extracellular RNA

Background

Both prokaryotic and eukaryotic cells are known to secrete RNA. The Endosomal Sorting Complex Required for Transport (ESCRT) machinery was previously considered as a possible mechanism for RNA secretion from the cell, but more recently research studying microRNA secretion in human embryonic kidney cells and Cercopithecus aethiops kidney cells identified neutral sphingomyelinase 2 (nSMase2), an enzyme involved in ceramide biosynthesis, as a regulator of microRNA secretion levels. ExRNAs are often found packaged within vesicles such as exosomes, ectosomes, prostasomes, microvesicles, and apoptotic bodies. Although RNAs can be excreted from the cell without an enveloping container, ribonucleases present in extracellular environments would eventually degrade the molecule.

Types of ExRNA

Extracellular RNA should not be viewed as a category describing a set of RNAs with a specific biological function or belonging to a particular RNA family. Similar to the term "non-coding RNA", "extracellular RNA" defines a group of several types of RNAs whose functions are diverse, yet they share a common attribute which, in the case of exRNAs, is existence in an extracellular environment. The following types of RNA have been found outside the cell:

Though prevalent inside of the cell, ribosomal RNA (rRNA) does not seem to be a common exRNA. Efforts by Valadi et al. to characterize exosomal RNA using the Agilent Bioanalyzer technology showed little to no trace of 18S and 28S rRNA in exosomes secreted by MC/9 murine mast cells, and similar conclusions were made by Skog et al. for rRNA in gliobastoma microvesicles.

Function

To successfully function in extracellular environments, exRNA is often enclosed within a vesicular body to prevent its digestion by RNases. In some cases such as its use in prokaryotic syntrophy, exRNA is not packaged because the recipient cells use the ribnonuclease-digested nucleotides. The use of extracellular vesicles to protect exRNA from degradation is believed to be linked with the use of these containers as a way to transport RNA between cells. Biochemical evidence supports the idea that exRNA uptake is a common process, suggesting new pathways for intercellular communication. As a result, the presence, absence, and relative abundance of certain exRNAs can be correlated with changes in cellular signaling and may indicate specific disease states.

Despite a limited understanding of exRNA biology, current research has shown the role of exRNAs to be multi-faceted. Extracellular miRNAs are capable of targeting mRNAs in the recipient cell through RNA interference pathways. In vitro experiments have shown the transfer of specific exRNAs into recipient cells inhibiting protein expression and preventing cancer cell growth. In addition to mRNAs being regulated by exRNAs, mRNAs can act as exRNAs to carry genetic information between cells. Messenger RNA contained in microvesicles secreted from glioblastomal cells were shown to generate a functional protein in recipient (human brain microvascular endothelial) cells in vitro. In another study of extracellular mRNAs, mRNAs transported by microvesicles from endothelial progenitor cells (EPCs) to human microvascular and macrovascular endothelial cells triggered angiogenesis in both the in vitro and in vivo setting. Work by Hunter et al. used Ingenuity Pathway Analysis (IPA) software that associated exRNAs found in human blood microvesicles with pathways involved in blood cell differentiation, metabolism, and immune function. These experimental and bioinformatics analyses favor the hypothesis that exRNAs play a role in numerous biological processes.

ExRNA Detection

Several methods have been developed or adapted to detect, characterize, and quantify exRNA from biological samples. RT-PCR, cDNA microarrays, and RNA sequencing are common techniques for RNA analysis. Applying these methods to study exRNAs mainly differs from cellular RNA experiments in the RNA isolation and/or extraction steps.

RT-PCR

For known exRNA nucleotide sequences, RT-PCR can be applied to detect their presence within a sample as well as quantify their abundance. This is done through first reverse transcribing the RNA sequence into cDNA. The cDNA then serves as a template for PCR amplification. The major benefits of using RT-PCR are its quantitative accuracy in a dynamic range and increased sensitivity compared to methods such as RNase protection assays and dot blot hybridization. The disadvantage to RT-PCR is the requirement of costly supplies, and the necessity of sound experimental design and an in-depth understanding of normalization techniques in order to obtain accurate results and conclusions.

Microfluidics

Microfluidic platforms such as the Agilent Bioanalyzer are useful in assessing the quality of exRNA samples. With the Agilent Bioanalyzer, a lab-on-chip technology that uses a sample of isolated RNA measures the length and quantity of RNA in the sample, and the results of the experiment can be represented as a digital electrophoresis gel image or an electropherogram. Because a diverse range of RNAs can be detected by this technology, it is an effective method for more generally determining what types of RNAs are present in exRNAs samples through using size characterization.

cDNA Microarrays

Microarrays allow for larger-scale exRNA characterization and quantification. Microarrays used for RNA studies first generate different cDNA oligonucleotides (probes) that are attached to the microarray chip. An RNA sample can then be added to the chip, and RNAs with sequence complementarity to the cDNA probe will bind and generate a fluorescent signal that can be quantified. Micro RNA arrays have been used in exRNA studies to generate miRNA profiles of bodily fluids.

RNA Sequencing

The advent of massively parallel sequencing (next-generation sequencing) lead to variations in DNA sequencing that allowed for high-throughput analyses of many genomic properties. Among these DNA sequencing-derived methods is RNA sequencing. The main advantage of RNA sequencing over other methods for exRNA detection and quantification is its high-throughput capabilities. Unlike microarrays, RNA sequencing is not constrained by factors such as oligonucleotide generation, and the number of probes that can be added to a chip. Indirect RNA sequencing of exRNA samples involves generating a cDNA library from the exRNAs followed by PCR amplification and sequencing. In 2009, Helicos Biosciences published a method for directly sequencing RNA molecules called Direct RNA sequencing (DRS™). Regardless of the RNA sequencing platform, inherent biases exist at various steps in the experiment, but methods have been proposed to correct for these biases with promising results.

Clinical Significance

As growing evidence supports the function of exRNAs as intercellular communicators, research efforts are investigating the possibility of utilizing exRNAs in disease diagnosis, prognosis, and therapeutics.

Biomarkers

The potential of extracellular RNAs to serve as biomarkers is significant not only because of their role in intercellular signaling but also due to developments in next generation sequencing that enable high throughput profiling. The simplest form of an exRNA biomarker is the presence (or absence) of a specific extracellular RNA. These biological signatures have been discovered in exRNA studies of cancer, diabetes, arthritis, and prion-related diseases. Recently, in a bioinformatics based analysis of extracellular vesicles (exosomes) extracted from Trypanosoma cruzi where SNPs were mined from transcriptomic data, [1] has showed the probability of finding biomarkers for chagas disease. This shows the significance of ExRNAs not only in the diseases like cancer but also neglected diseases as well.

Cancer

A major research area of interest for exRNA has been its role in cancer. The table below (adapted from Kosaka et al.) lists several types of cancer in which exRNAs have been shown to be associated: