Abstract

Citation:Gómez G, Pallás V (2010) Noncoding RNA Mediated Traffic of Foreign mRNA into Chloroplasts Reveals a Novel Signaling Mechanism in Plants. PLoS ONE 5(8): e12269. https://doi.org/10.1371/journal.pone.0012269

Editor:Baohong Zhang, East Carolina University, United States of America

Received:July 2, 2010;Accepted:July 26, 2010;Published: August 19, 2010

Copyright: © 2010 Gómez, Pallás. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

Funding:This work was supported by grant BIO2008-03528 from the Spanish granting agency DGICYT (www.micinn.es). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

Competing interests: The authors have declared that no competing interests exist.

Introduction

Chloroplasts are the hallmark organelle of photosynthetic eukaryotes[1],[2]. They are responsible for many metabolic processes, including photosynthesis and biosynthesis of diverse essentials primary and secondary metabolites[3]–[5]. These organelles arose from cyanobacterium-like ancestors that were engulfed by eukaryotic cells during the endosymbiotic evolution[6]. Although chloroplasts have maintained remnants of the ancestral genome, the majority of the genes encoding chloroplast proteins have been transferred to the plant genome. Consequently, most of the proteins found in this organelle are nucleus-encoded[1],[2],[7].

The exchange of genetic information between the nucleus and the chloroplast has resulted in a close coordination in the activities of these two organelles during plant development which is mediated by both anterograde (nucleus-chloroplast) and retrograde (chloroplast-nucleus) signals[2],[5]. Thus, signaling between plastids and nucleus is required to maintain chloroplast biological functions. It is widely accepted that this genome-coordinated mechanism is mediated by proteins encoded in the nucleus, synthesized in the cytosol in the corresponding precursor form (containing a targeting signal called transit peptide, TP) and then imported into the organelle[7]. However, the identification, in recent years of a significant number of nuclear-encoded proteins lacking canonical transit-peptides[8],[9] supports the existence of alternative pathways in plant cell that tune the accumulation of host proteins in chloroplasts[1].

High-throughput sequencing methods have unveiled a complex network of transcripts derived from the eukaryotic genome that include a large number of noncoding RNAs (ncRNAs)[10]–[12]. NcRNAs are increasingly recognized as regulators of gene expression and the other cellular functions, playing roles previously believed to correspond to proteins[10]–[12]. Although ncRNAs were thought to be restricted to the nuclear or cytosolic compartments of the cell, these regulatory RNAs were also identified in mitochondria and chloroplasts mapping to intergenic regions of the organellar genome[13].

Viroids are small ncRNAs that infect plants[14]–[16]. They are classified into two families:Pospiviroidae and theAvsunviroidae. Members of the familyAvsunviroidae replicate and accumulate in the chloroplast and are the only functional RNAs that have been reported to traffic inside this organelle[15],[16]. Elucidating mechanisms used by these pathogens to enter chloroplasts will unearth novel transport pathways in plant cells.

Here we report that a viroid-derived ncRNA sequence acting as 5′UTR (vd-5′UTR) mediates the specific import of a functional GFP mRNA into the chloroplasts ofN. benthamiana cells, thus supporting the existence of a novel signaling mechanism between the host cell and these organelles.

Results and Discussion

The use of transcriptional fusion between viroid derived sequences and the mRNA of a reporter protein were previously described to analyze plant-specific cellular processes such as RNA silencing or viroid-induced pathogenesis[17],[18]. Consequently, to evaluate if an ncRNA could regulate the transport of mRNAs to chloroplasts, we constructed a chimeric DNA containing a modifiedEggplant latent viroid (ELVd)[19] cDNA sequence fused as an untranslated region (UTR) to the 5′end of the cDNA of the Green Fluorescence Protein (GFP) (Figure 1A). The fused viroid-GFP cDNA (vd-5′UTR-GFP) was cloned in a binary vector and transfected intoAgrobacterium tumefaciens. The correct transcriptional fusion of the vd-5′UTR-GFP fragments was checked by DNA sequencing and byin silico translation of the chimeric mRNA (Figure 2). The functionality of this chimeric transcript was analyzed by comparing its transient expression with that of the unmodified GFP mRNA inN. benthamiana plants in agroinfiltration assays. Total proteins were extracted from agroinfiltrated leaves and analyzed by Western blot assays. As observed inFigure 1B the unmodified GFP and vd-5′UTR-GFP, show a similar relative electrophoretic mobility, indicating that the viroid-derived ncRNA act in this chimeric transcript as a true 5′ untranslated region of the GFP mRNA, thus verifying the prediction performedin silico.

Download:

• PPT
  PowerPoint slide
• PNG
  larger image
• TIFF
  original image

Figure 1. Transcriptional fusion of viroid derived 5′UTR end to GFP cDNA.

(A) Physical map of the vd-5′UTR/GFP construct. (B) Serological detection of the vd-5′UTR/GFP. Total proteins were extracted from infiltrated leaves, electrophoresed in 10% SDS-PAGE (upper panel) and blotted for serological detection (lower panel). The vd-5′UTR/GFP and the GFP were clearly detected and show similar relative electrophoretic mobility, indicating that the viroid derived sequence acts as a true untranslated RNA. Three 1∶5 serial dilutions are sown for each construct. MwS: Molecular weight standard.

https://doi.org/10.1371/journal.pone.0012269.g001

Download:

• PPT
  PowerPoint slide
• PNG
  larger image
• TIFF
  original image

Figure 2. Details of the fusion ELVd-derived RNA/GFP mRNA.

(A) Partial DNA sequence of the vd-5′UTR-GFP construct (AN - HM136583) used in this study. (B) In silico predicted translation of the vd-5′UTR-GFP transcript.

https://doi.org/10.1371/journal.pone.0012269.g002

When the infiltrated plants were analyzed by confocal microscopy we observed that the unmodified GFP (used as a control) was uniformly distributed in the nucleus and cytoplasm of the examined cells (Figure 3, left panels), while the GFP arising from the vd-5′UTR/GFP transcript was largely localized in the chloroplasts (Figure 3, central panels). The chloroplastic localization of the vd-5′UTR/GFP was confirmed by a comparative analysis using a GFP fused to a chloroplast-specific transit peptide derived of a protein of the oxygen evolving complex (OE23) as reference[20]. As observed inFigure 3 the vd-5′UTR/GFP mimics the cellular localization of the OE23/GFP construct that specifically accumulated in the chloroplasts ofN. benthamiana cells (right panels) thus confirming that the GFP translated from the chimeric transcript vd-5′UTR/GFP accumulates specifically in this organelle.

Download:

• PPT
  PowerPoint slide
• PNG
  larger image
• TIFF
  original image

Figure 3. The GFP arising from vd-5′UTR/GFP transcripts accumulate specifically in chloroplasts.

Confocal microscope observation of theN. benthamiana leaves expressing unmodified GFP (left panels), vd-5′UTR-GFP (central panels) or OE23/GFP (right panels). As observed, the vd-5′UTR/GFP mimics the cellular localization of the OE23/GFP construct that accumulates specifically in chloroplasts.

https://doi.org/10.1371/journal.pone.0012269.g003

To demonstrate the chloroplastic localization of the chimeric transcripts, we isolated chloroplasts fromN. benthamiana cells expressing the GFP or vd-5′UTR/GFP constructs (Figure 4A), and analyzed the accumulation of GFP mRNA in these organelles by RT-PCR. As seen inFigure 4B (upper panel), the GFP transcripts were detected in the chloroplasts isolated from the cells expressing the vd-5′UTR/GFP, but not in those isolated from the cells expressing unmodified GFP. The 28 s rRNA used as a control of isolated-chloroplasts integrity was similarly detected in both GFP mRNA-accumulating and non GFP mRNA-accumulating organelles (Figure 4B, bottom panel). This finding provides direct evidence that the vd-5′UTR-GFP mRNA transcribed in the nucleus ofN. benthamiana cells is specifically targeted to chloroplasts where, according to the confocal microscopy experiments, it is efficiently retained and translated in functional GFP.

Download:

• PPT
  PowerPoint slide
• PNG
  larger image
• TIFF
  original image

Figure 4. Vd-5′UTR mediates the traffic of functional GFP-mRNA to chloroplasts.

(A) Confocal microscope observation of chloroplasts isolated from leaves expressing GFP or vd-5′UTR/GFP. (B) RT-PCR analysis of GFP transcripts extracted from chloroplasts isolated from leaves infiltrated with both constructs. Chloroplast ribosomal RNA 28 s was amplified as a control of isolated-chloroplasts integrity.

https://doi.org/10.1371/journal.pone.0012269.g004

In short, our results demonstrate that an ncRNA fused as a 5′UTR end acts as a key regulatory molecule which is able to mediate the specific trafficking of a functional foreign mRNA into the chloroplast, thus supporting the existence of a novel signaling mechanism between the host cell and chloroplasts. This emergent paradigm highlights a novel host-modulated regulatory mechanism that would be potentially able to control the gene expression and the accumulation of the nuclear-encoded proteins in chloroplasts, as an alternative to that based on transit-peptides. Interestingly, the search for entirely new mechanisms involved in this crucial transport system has been recently enunciated as a major priority for future research in the field of chloroplasts protein targeting[2]. In this context, it is reasonable to assume that theAvsunviroidae family viroid members have probably evolved to subvert this signaling mechanism in order to regulate their differential traffic and accumulation into the chloroplast of infected plant cells.

Indirect evidence may suggest that, at least in parasitic plants which plastid genome lacks most, if not all, of the photosynthetic genes, tRNAs must be imported from outside the plastid[21]. In a previous work it was shown that the mRNA coding for the eukaryotic translation factor 4E, an essential regulator of translation, enters the chloroplasts in four different plant species[22]. In addition, the localization in the chloroplasts of an heterologous GFP mRNA fused to the eIF4E RNA was also observed. However, the eIF4E protein was not detected in the chloroplast and thus, to date, the import of functional RNAs into chloroplasts has not been directly demonstrated. Our results demonstrate for the first time that an RNA sequence is able to transport to chloroplastsper se and that it is functional in this organelle.

Finally, the use of plant chloroplasts as bioreactors has emerged in the last years as a valuable biotechnological alternative to microbial fermentation and mammalian cell culture for the industrial production of diverse compounds[23]–[26]. Consequently, the description of a ncRNA acting as an untranslated signal capable of mediating the stable expression of foreign proteins in the chloroplast provides a conceptual framework to develop alternative strategies in the production of biopharmaceuticals or vaccines in systems using plant chloroplasts as bioreactors.

Materials and Methods

Acknowledgments

We thank Dr M. Fares form critical reading of this manuscript. G. Gomez is the recipient of a contract from the CSIC.

Author Contributions

Conceived and designed the experiments: GG. Performed the experiments: GG. Analyzed the data: GG VP. Wrote the paper: GG VP.

References

1. 1.Woodson JD, Chory J (2008) Coordination of gene expression between organellar and nuclear genomes. Nat Rev 9: 383–395.
   • View Article
   • Google Scholar
2. 2.Jarvis P (2008) Targeting of nucleus-encoded proteins to chloroplasts in plants. New Phytol 179: 257–285.
   • View Article
   • Google Scholar
3. 3.Lopez-Juez E, Pyke K (2005) Plastids unleashed: their development and their integration in plant development. Int J Dev Biol 49: 557–577.
   • View Article
   • Google Scholar
4. 4.Nelson N, Ben-Shem A (2004) The complex architecture of oxygenic photosynthesis. Nat Rev Mol Cell Biol 5: 971–982.
   • View Article
   • Google Scholar
5. 5.Pogson BJ, Woo NS, Förster B, Small ID (2008) Plastid signaling to the nucleus and beyond. Trends Plant Sci 13: 602–609.
   • View Article
   • Google Scholar
6. 6.Dyall SD, Brown MT, Johnson PJ (2004) Ancient invasions: from endosymbionts to organelles. Science 304: 253–257.
   • View Article
   • Google Scholar
7. 7.Bruce BD (2000) Chloroplast transit peptides: structure, function and evolution. Trends Cell Biol 10: 440–447.
   • View Article
   • Google Scholar
8. 8.Nada A, Soll J (2004) Inner envelope protein 32 is imported into chloroplasts by a novel pathway. J Cell Sci 117: 3975–3982.
   • View Article
   • Google Scholar
9. 9.Kleffmann T, Russenberger D, von Zychlinski A, Christopher W, Sjölander K, et al. (2004) The Arabidopsis thaliana chloroplast proteome reveals pathway abundance and novel protein functions. Curr Biol 14: 354–362.
   • View Article
   • Google Scholar
10. 10.Rymarquis LA, Kastenmayer JP, Hüttenhofer AG, Green P (2008) Diamonds in the rough: mRNA-like ncRNAs. Trends Plant Sci 13: 329–334.
    • View Article
    • Google Scholar
11. 11.Wilusz JE, Sunwoo H, Spector DL (2009) Long noncoding RNAs: functional surprises from the RNA world. Genes Dev 23: 1494–1504.
    • View Article
    • Google Scholar
12. 12.Hannapel DJ (2010) A model system of development regulated by the long-distance transport of mRNA. J Integr Plant Biol 52: 40–52.
    • View Article
    • Google Scholar
13. 13.Lung B, Zemann A, Madej MJ, Schuelke M, Techritz S, et al. (2006) Identification of small non-coding RNAs from mitochondria and chloroplasts. Nucleic Acids Res 34: 3842–3852.
    • View Article
    • Google Scholar
14. 14.Ding B (2009) The biology of viroid-host interactions. Annu Rev Phytopathol 47: 105–131.
    • View Article
    • Google Scholar
15. 15.Gómez G, Martinez G, Pallás V (2009) Trends Plant Sci 14: 264–269.
    • View Article
    • Google Scholar
16. 16.Daròs JA, Elena SF, Flores R (2006) Viroids: an Ariadne's thread into the RNA labyrinth. EMBO Rep 7: 593–598.
    • View Article
    • Google Scholar
17. 17.Gómez G, Pallás V (2007) Mature monomeric forms of Hop stunt viroid resist RNA silencing in transgenic plants. Plant J 51: 1041–1049.
    • View Article
    • Google Scholar
18. 18.Gómez G, Martinez G, Pallas V (2008) Viroid-induced symptoms inNicotiana benthamiana plants are dependent on RDR6 activity. Plant Physiol 148: 414–423.
    • View Article
    • Google Scholar
19. 19.Fadda Z, Daròs JA, Fagoaga C, Flores R, Duran-Vila N (2003)Eggplant latent viroid, the candidate type species for a new genus within the familyAvsunviroidae. J Virol 77: 6528–6532.
    • View Article
    • Google Scholar
20. 20.Roffey RA, Theg SM (1996) Analysis of the import of carboxyl-terminal truncations of the 23-kilodalton subunit of the Oxygen-Evolving Complex suggests that its structure is an important determinant for thylakoid transport. Plant Physiol 111: 1329–1338.
    • View Article
    • Google Scholar
21. 21.Bungard RA (2004) Photosynthetic evolution in parasitic plants: insight from the chloroplast genome. Bioessays 26: 235–247.
    • View Article
    • Google Scholar
22. 22.Nicolai M, Duprat A, Sormani R, Rodriguez C, Roncato MA, et al. (2007) Higher plant chloroplasts import the mRNA coding for the eukaryotic translation initiation factor 4E. FEBS Letters 581: 3921–3926.
    • View Article
    • Google Scholar
23. 23.Verma D, Samson NP, Koya V, Daniell H (2008) A protocol for expression of foreign genes in chloroplasts. Nat Protoc 3: 739–758.
    • View Article
    • Google Scholar
24. 24.Daniell H, Singh ND, Mason H, Streatfield SJ (2009) Plant-made vaccine antigens and biopharmaceuticals. Trends Plant Sci 14: 669–679.
    • View Article
    • Google Scholar
25. 25.Floss DM, Falkenburg D, Conrad U (2007) Production of vaccines and therapeutic antibodies for veterinary applications in transgenic plants: an overview. Transgenic Res 16: 315–332.
    • View Article
    • Google Scholar
26. 26.Koya V, Moayeri M, Leppla SH, Daniell H (2005) Plant based vaccine: mice immunized with chloroplast-derived anthrax protective antigen survive anthrax lethal toxin challenge. Infect Immun 73: 8266–8274.
    • View Article
    • Google Scholar
27. 27.Knoester M, van Loon LC, van den Heuvel J, Hennig J, Bol JF, et al. (1998) Ethylene-insensitive tobacco lacks non host resistance against soil-borne fungi. Proc Natl Acad Sci U S A 95: 1933–1937.
    • View Article
    • Google Scholar
28. 28.Fan P, Wang X, Kuang T, Li Y (2009) An efficient method for the extraction of chloroplast protein compatible for 2-DE and MS analysis. Electrophoresis 30: 3024–3033.
    • View Article
    • Google Scholar