Sergey I. Ivashuta

Lack of detectable oral bioavailability of plant microRNAs after feeding in mice

965 chow preparation where we observed the expected distribution and abundance of rice miRNAs. Oryza sativa (rice) osa-miR168a was among the most abundant miRNAs (Supplementary Table 1) in both ricecontaining chow and rice grain, consistent with previous reports9,12. Diet composition had no impact on food consumption (Supplementary Fig. 1). Following completion of the feeding regimen, small RNAs were sequenced from mouse liver and plasma samples using the Illumina (San Diego) HiSeq system. Details of the experimental protocols can be found in Supplementary Methods. We observed the expected endogenous miRNA profile and miRNA length distribution in mouse plasma and liver and rice samples, indicating consistent quality of the small RNA sequencing procedure (Supplementary Fig. 2a,b). Analysis of small RNAs from plasma and liver of mice fed on balanced rice chow and rice chow did not reveal measurable uptake of any rice grain miRNAs, including osa-miR168a. Of >10 million total sequence reads per library, fewer than ten reads identical to known rice miRNAs per library were noted in five out of eight samples from mice fed on rice-containing chow and four out of five samples from mice fed on synthetic chow (Table 1). Synthetic chow did not contain any grain or forage from plants (all plant-derived ingredients were highly purified isolates, for example, cornstarch and soybean oil); therefore, these low number of rice miRNAmappable reads could be explained by sequence errors or by cross-contamination. Mapping of mouse small RNA data to all annotated rice miRNAs in miRBase v19 identified a low number of mouse small RNA reads identical to several rice miRNA sequences (Table 1). Even so, most of the rice-like sequences were identical to the miR414 sequence (Supplementary Table 1), which is not detectable in rice grain12. In addition, these plant-like sequences were present in similar quantities in all mouse To the Editor: Human therapeutics based on nucleic acid targeting rely on sequence-specific interactions between effector and target molecules to achieve beneficial effects through specific modification to the expression of targeted genes. A variety of such compounds are being tested in laboratories and in clinical trials to treat a range of genetic and acquired diseases. Efficient, safe and cost-effective delivery of nucleic acid–based drug candidates is required to enable therapeutic levels of targeted gene regulation and overall success of this exciting new class of therapeutics. For several types of compounds in this class, effective drug delivery relies on injection of formulated nucleic acids at the site of action or into the bloodstream. Oral delivery would excel as a treatment strategy as it could offer convenient and patient-friendly features, however, progress in this approach has been hampered by substantial challenges associated with biological barriers that limit oral activity of nucleic acid therapeutics (e.g., stability within and uptake of nucleic acids from the mammalian gastrointestinal tract, nucleases and membrane barriers)1. Considerable effort has been applied to improve the stability and uptake efficiency of orally administered nucleic acids by introducing chemical modifications and formulating with excipients; however, limited success has been reported thus far2,3. The naturally occurring RNA interference (RNAi) response has been extensively reported after feeding double-stranded RNA (dsRNA) in some invertebrates, such as the model organism Caenorhabditis elegans4 and some agricultural pests5,6 (e.g., corn rootworm and cotton bollworm). Yet, despite responsiveness to ingested dsRNA, a recent survey revealed substantial variation in sensitivity to dsRNA in other Caenorhabditis nematodes7 and other invertebrate species8. In addition, despite major efforts in academic and pharmaceutical laboratories to activate the RNA silencing pathway in response to ingested RNA, the phenomenon had not been reported in mammals until a recent publication by Zhang et al.9 in Cell Research. This report described the uptake of plant-derived microRNAs (miRNA) into the serum, liver and a few other tissues in mice following consumption of rice, as well as apparent gene regulatory activity in the liver. The observation provided a potentially groundbreaking new possibility that RNAbased therapies could be delivered to mammals through oral administration and at the same time opened a discussion on the evolutionary impact of environmental dietary nucleic acid effects across broad phylogenies. A recently reported survey of a large number of animal small RNA datasets from public sources has not revealed evidence for any major plant-derived miRNA accumulation in animal samples10. Given the number of questions evoked by these analyses, the limited success with oral RNA delivery for pharmaceutical development, the history of safe consumption for dietary small RNAs11 and lack of evidence for uptake of plant-derived dietary small RNAs, we felt further evaluation of miRNA uptake and the potential for cross-kingdom gene regulation in animals was warranted to assess the prevalence, impact and robustness of the phenomenon. To address this question, we conducted a well-controlled mouse feeding study with rice-containing chow diets or with a purified synthetic chow devoid of plant grain or forage. After a two-week acclimation on synthetic chow (modified AIN93-G), animals were fasted for 12 h and then placed on synthetic chow; a nutritionally balanced, rice-containing chow (modified AIN93-G with 40.8% rice); or rice-based chow (75% rice), for 1, 3 and 7 days (Supplementary Methods). These groups are referred to herein as synthetic chow, balanced rice chow and rice chow, respectively. To confirm rice miRNA availability in feeding material, we first sequenced rice small RNAs from ricecontaining chow and rice grains used for Lack of detectable oral bioavailability of plant microRNAs after feeding in mice correspondence

Analysis of plant-derived miRNAs in animal small RNA datasets

BackgroundPlants contain significant quantities of small RNAs (sRNAs) derived from various sRNA biogenesis pathways. Many of these sRNAs play regulatory roles in plants. Previous analysis revealed that numerous sRNAs in corn, rice and soybean seeds have high sequence similarity to animal genes. However, exogenous RNA is considered to be unstable within the gastrointestinal tract of many animals, thus limiting potential for any adverse effects from consumption of dietary RNA. A recent paper reported that putative plant miRNAs were detected in animal plasma and serum, presumably acquired through ingestion, and may have a functional impact in the consuming organisms.ResultsTo address the question of how common this phenomenon could be, we searched for plant miRNAs sequences in public sRNA datasets from various tissues of mammals, chicken and insects. Our analyses revealed that plant miRNAs were present in the animal sRNA datasets, and significantly miR168 was extremely over-represented. Furthermore, all or nearly all (>96%) miR168 sequences were monocot derived for most datasets, including datasets for two insects reared on dicot plants in their respective experiments. To investigate if plant-derived miRNAs, including miR168, could accumulate and move systemically in insects, we conducted insect feeding studies for three insects including corn rootworm, which has been shown to be responsive to plant-produced long double-stranded RNAs.ConclusionsOur analyses suggest that the observed plant miRNAs in animal sRNA datasets can originate in the process of sequencing, and that accumulation of plant miRNAs via dietary exposure is not universal in animals.

Posttranscriptional gene silencing in nuclei

In plants, small interfering RNAs (siRNAs) with sequence homology to transcribed regions of genes can guide the sequence-specific degradation of corresponding mRNAs, leading to posttranscriptional gene silencing (PTGS). The current consensus is that siRNA-mediated PTGS occurs primarily in the cytoplasm where target mRNAs are localized and translated into proteins. However, expression of an inverted-repeat double-stranded RNA corresponding to the soybean FAD2-1A desaturase intron is sufficient to silence FAD2-1, implicating nuclear precursor mRNA (pre-mRNA) rather than cytosolic mRNA as the target of PTGS. Silencing FAD2-1 using intronic or 3′-UTR sequences does not affect transcription rates of the target genes but results in the strong reduction of target transcript levels in the nucleus. Moreover, siRNAs corresponding to pre-mRNA–specific sequences accumulate in the nucleus. In Arabidopsis, we find that two enzymes involved in PTGS, Dicer-like 4 and RNA-dependent RNA polymerase 6, are localized in the nucleus. Collectively, these results demonstrate that siRNA-directed RNA degradation can take place in the nucleus, suggesting the need for a more complex view of the subcellular compartmentation of PTGS in plants.

Regulation of Gene Expression in Plants through miRNA Inactivation

Eukaryotic organisms possess a complex RNA-directed gene expression regulatory network allowing the production of unique gene expression patterns. A recent addition to the repertoire of RNA-based gene regulation is miRNA target decoys, endogenous RNA that can negatively regulate miRNA activity. miRNA decoys have been shown to be a valuable tool for understanding the function of several miRNA families in plants and invertebrates. Engineering and precise manipulation of an endogenous RNA regulatory network through modification of miRNA activity also affords a significant opportunity to achieve a desired outcome of enhanced plant development or response to environmental stresses. Here we report that expression of miRNA decoys as single or heteromeric non-cleavable microRNA (miRNA) sites embedded in either non-protein-coding or within the 3′ untranslated region of protein-coding transcripts can regulate the expression of one or more miRNA targets. By altering the sequence of the miRNA decoy sites, we were able to attenuate miRNA inactivation, which allowed for fine regulation of native miRNA targets and the production of a desirable range of plant phenotypes. Thus, our results demonstrate miRNA decoys are a flexible and robust tool, not only for studying miRNA function, but also for targeted engineering of gene expression in plants. Computational analysis of the Arabidopsis transcriptome revealed a number of potential miRNA decoys, suggesting that endogenous decoys may have an important role in natural modulation of expression in plants.

Environmental RNAi in herbivorous insects

Environmental RNAi (eRNAi) is a sequence-specific regulation of endogenous gene expression in a receptive organism by exogenous double-stranded RNA (dsRNA). Although demonstrated under artificial dietary conditions and via transgenic plant presentations in several herbivorous insects, the magnitude and consequence of exogenous dsRNA uptake and the role of eRNAi remains unknown under natural insect living conditions. Our analysis of coleopteran insects sensitive to eRNAi fed on wild-type plants revealed uptake of plant endogenous long dsRNAs, but not small RNAs. Subsequently, the dsRNAs were processed into 21 nt siRNAs by insects and accumulated in high quantities in insect cells. No accumulation of host plant-derived siRNAs was observed in lepidopteran larvae that are recalcitrant to eRNAi. Stability of ingested dsRNA in coleopteran larval gut followed by uptake and transport from the gut to distal tissues appeared to be enabling factors for eRNAi. Although a relatively large number of distinct coleopteran insect-processed plant-derived siRNAs had sequence complementarity to insect transcripts, the vast majority of the siRNAs were present in relatively low abundance, and RNA-seq analysis did not detect a significant effect of plant-derived siRNAs on insect transcriptome. In summary, we observed a broad genome-wide uptake of plant endogenous dsRNA and subsequent processing of ingested dsRNA into 21 nt siRNAs in eRNAi-sensitive insects under natural feeding conditions. In addition to dsRNA stability in gut lumen and uptake, dosage of siRNAs targeting a given insect transcript is likely an important factor in order to achieve measurable eRNAi-based regulation in eRNAi-competent insects that lack an apparent silencing amplification mechanism.

Endogenous small RNAs in grain: Semi-quantification and sequence homology to human and animal genes

Small interfering RNAs (siRNAs) and microRNAs (miRNAs) are effector molecules of RNA interference (RNAi), a highly conserved RNA-based gene suppression mechanism in plants, mammals and other eukaryotes. Endogenous RNAi-based gene suppression has been harnessed naturally and through conventional breeding to achieve desired plant phenotypes. The present study demonstrates that endogenous small RNAs, such as siRNAs and miRNAs, are abundant in soybean seeds, corn kernels, and rice grain, plant tissues that are traditionally used for food and feed. Numerous endogenous plant small RNAs were found to have perfect complementarity to human genes as well as those of other mammals. The abundance of endogenous small RNA molecules in grain from safely consumed food and feed crops such as soybean, corn, and rice and the homology of a number of these dietary small RNAs to human and animal genomes and transcriptomes establishes a history of safe consumption for dietary small RNAs.

Functional diversification of maize RNA polymerase IV and V subtypes via alternative catalytic subunits

Unlike nuclear multisubunit RNA polymerases I, II, and III, whose subunit compositions are conserved throughout eukaryotes, plant RNA polymerases IV and V are nonessential, Pol II-related enzymes whose subunit compositions are still evolving. Whereas Arabidopsis Pols IV and V differ from Pol II in four or five of their 12 subunits, respectively, and differ from one another in three subunits, proteomic analyses show that maize Pols IV and V differ from Pol II in six subunits but differ from each other only in their largest subunits. Use of alternative catalytic second subunits, which are nonredundant for development and paramutation, yields at least two subtypes of Pol IV and three subtypes of Pol V in maize. Pol IV/Pol V associations with MOP1, RMR1, AGO121, Zm_DRD1/CHR127, SHH2a, and SHH2b extend parallels between paramutation in maize and the RNA-directed DNA methylation pathway in Arabidopsis.

A novel real‐time polymerase chain reaction method for high throughput quantification of small regulatory RNAs

MicroRNAs (miRNAs) and small interfering RNAs (siRNAs) are important players of both transcriptional and post-transcriptional gene silencing networks. In order to investigate the functions of these small regulatory RNAs, a system with high sensitivity and specificity is desperately needed to quantitatively detect their expression levels in cells and tissues. However, their short length of 19-24 nucleotides and strong similarity between related species render most conventional expression analysis methods ineffective. Here we describe a novel primer for small RNA-specific reverse transcription and a new TaqMan technology-based real-time method for quantification of small RNAs. This method is capable of quantifying miRNA and siRNA in the femtomolar range, which is equivalent to ten copies per cell or fewer. The assay has a high dynamic range and provides linear readout of miRNA concentrations that span seven orders of magnitude and allows us to discriminate small RNAs that differ by as little as one nucleotide. Using the new method, we investigated the expression pattern of gma-miRMON1, a novel miRNA identified from soybean leaves. The results were consistent with our results obtained from Northern blot analysis of gma-miRMON1 and Affymetrix microarray analysis of the gma-miRMON1 precursor, suggesting that the new method can be used in transcription profiling.

RNA decoys: an emerging component of plant regulatory networks?

The role of non-coding RNAs (ncRNAs), both short and long ncRNAs, in the regulation of gene expression has become evident in recent years. Non-coding RNA-based regulation is achieved through a variety of mechanisms; some are relatively well-characterized, while others are much less understood. MicroRNAs (miRNAs), a class of endogenous small RNAs, function as master regulators of gene expression in eukaryotic organisms. A notable, recently discovered role for long ncRNAs is that of miRNA decoys, also referred to as target mimics or sponges, in which long ncRNAs carry a short stretch of sequence sharing homology to miRNA-binding sites in endogenous targets. As a consequence, miRNA decoys are able to sequester and inactivate miRNA function. Engineered miRNA decoys are also efficacious and useful tools for studying gene function. We recently demonstrated that the potential of miRNA decoys to inactivate miRNAs in the model plants Arabidopsis thaliana and Nicotiana benthamiana is dependent on the level of sequence complementarity to miRNAs of interest. The flexibility of the miRNA decoy approach in sequence-dependent miRNA inactivation, backbone choice, ability to simultaneously inactivate multiple miRNAs, and more importantly, to achieve a desirable level of miRNA inactivation, makes it a potentially useful tool for crop improvement. This research addendum reports the functional extension of miRNA decoys from model plants to crops. Furthermore, endogenous miRNA decoys, first described in plants, have been proposed to play a significant role in regulating the transcriptome in eukaryotes. Using computational analysis, we have identified numerous endogenous sequences with potential miRNA decoy activity for conserved miRNAs in several plant species. Our data suggest that endogenous miRNA decoys can be widespread in plants and may be a component of the global gene expression regulatory network in plants.

Computational sequence analysis of predicted long dsRNA transcriptomes of major crops reveals sequence complementarity with human genes

Long double-stranded RNAs (long dsRNAs) are precursors for the effector molecules of sequence-specific RNA-based gene silencing in eukaryotes. Plant cells can contain numerous endogenous long dsRNAs. This study demonstrates that such endogenous long dsRNAs in plants have sequence complementarity to human genes. Many of these complementary long dsRNAs have perfect sequence complementarity of at least 21 nucleotides to human genes; enough complementarity to potentially trigger gene silencing in targeted human cells if delivered in functional form. However, the number and diversity of long dsRNA molecules in plant tissue from crops such as lettuce, tomato, corn, soy and rice with complementarity to human genes that have a long history of safe consumption supports a conclusion that long dsRNAs do not present a significant dietary risk.