Pocket K No. 34: RNAi for Crop Improvement


Introduction

RNA interference (RNAi) is a method of blocking gene function by inserting short sequences of ribonucleic acid (RNA) that match part of the target gene’s sequence, thus no proteins are produced. Since Science named it as “Breakthrough of the Year” and Fortune magazine hailed it as “Biotech’s Billion Dollar Breakthrough” in 2003, RNAi has significantly gained prominence as the method of choice for researchers sleuthing the structure and function of important genes.

RNAi has the potential to become a powerful therapeutic approach toward targeted and personalized medicine.  The range of diseases and disorders it might address is unprecedented; from cancer to cardiovascular diseases, neurodegenerative disorders and even HIV. Even more exciting is the potential of RNAi in agriculture. RNAi has provided a way to control pests and diseases, introduce novel plant traits and increase crop yield. Using RNAi, scientists have developed novel crops such as nicotine-free tobacco, non-allergenic peanuts, decaffeinated coffee, and nutrient fortified maize among many others.

Discovery of RNAi

Complete plant genome sequences has brought new dimensions in genetic modification to improve plant characteristics. Scientists believed that they could produce any gene products by just introducing foreign genes in plants, which was not always the case1. Plant biologists found out that introducing multiple copies of a gene that codes for purple petunia flowers led, not as expected to a deeper purple hue, but rather to plants with white or variegated flowers. Through an unknown mechanism, the introduced transgenes were silenced as well as the plant’s ‘purple-flower’ gene2,3. In another research, gene silencing was also observed when plants were infected with RNA viruses engineered to contain fragments of the plant gene.

The mechanism causing these effects was not known until American scientists Andrew Fire and Craig Mello discovered that injecting double stranded ribonucleic acids (dsRNA) into the worm Caenorhabditis elegans triggered the silencing of genes with sequences identical to that of the dsRNA4. They called the phenomenon RNA interference. Re-examining the co-suppression pathway in petunia and virus-induced gene silencing revealed that all these processes led to the accumulation of dsRNAs, hence the RNAi pathway. Fire and Mello were awarded the 2006 Nobel price for Physiology or Medicine for their discovery.

In addition to its roles in regulating gene expression, RNAi is used as an immune response to infection5 and as a natural defense mechanism against molecular parasites such as jumping genes and viral genetic elements that affect genome stability6. Specific types of bacteria have also been shown to trigger the RNAi pathway in plants.

 

How RNAi Works

  1. The entry of long double stranded RNA, such as an introduced transgene, a rogue genetic element or a viral intruder, triggers the RNAi pathway of cells. This results in the recruitment of the enzyme Dicer.
  2. Dicer cleaves the dsRNA into short, 20-25 basepairs long, fragments, called small interfering RNA (siRNA).
  3. An RNA-induced silencing complex (RISC) then distinguishes between the two siRNA strands as either sense or antisense. The sense strands (with exactly the same sequence as the target gene) are degraded.
  4. The antisense strands on the other hand are incorporated to the RISC. These are used as guide to target messenger RNAs (mRNA) in a sequence-specific manner.
  5. Messenger RNAs (mRNA), which codes for amino acids, are cleaved by RISC. The activated RISC can repeatedly participate in mRNA degradation, inhibiting protein synthesis.


Figure 1.  Mechanism of RNAi

 

RNAi for Disease and Pathogen Resistance

Gene silencing was first used to develop plant varieties resistant to viruses. Engineered antiviral strategies in plants mimic natural RNA silencing mechanisms. This was first demonstrated when scientists developed Potato virus Y- resistant plants expressing RNA transcripts of a viral proteinase gene7,8. Immunity has since been shown to other viruses such as the Cucumber and Tobacco Mosaic Virus, Tomato Spotted Wilt Virus, Bean Golden Mosaic Virus, Banana Bract Mosaic Virus, and Rice Tungro Bacilliform Virus among many others.
In addition, plants can also be modified to produce dsRNAs that silence essential genes in insect pests and parasitic nematodes. This approach was used to develop root-knot nematode9, corn rootworm10 and cotton bollworm11  resistant varieties.

RNAi for Male Sterility

RNAi has also been used to generate male sterility, which is valuable in the hybrid seed industry. Genes that are expressed solely in tissues involved in pollen production can be targeted through RNAi. For instance, scientists have developed male sterile tobacco lines by inhibiting the expression of TA29, a gene necessary for pollen development12. RNAi was also used to disrupt the expression of Msh1 in tobacco and tomato resulting to rearrangements in the mitochondrial DNA associated with naturally occurring cytoplasmic male sterility13.

RNAi and Plant Functional Genomics

A major challenge in the post-genomic era of plant biology is to determine the functions of all genes in the plant genome16. Compared to other techniques, RNAi offers specificity and efficacy in silencing members of a gene or multiple gene family. In addition, the expression of dsRNAs with inducible promoters can control the extent and timing of gene silencing, such that essential genes are only silenced at chosen growth stages or plant organs14, 15.

There are several ways of activating the RNAi pathway in plants. The various RNAi techniques have advantages and disadvantages with respect to how persistent their effects are and the range of plants to which they can be applied. These include the use of hairpin RNA-expressing vectors, particle bombardment, Agrobacterium- mediated transformation and virus-induced gene silencing (VIGS) 16.

Engineering Plant Metabolic Pathways through RNAi

RNAi has been used to modify plant metabolic pathways to enhance nutrient content and reduced toxin production (Summarized in Table 1). The technique takes advantage of the heritable and stable RNAi phenotypes in plants.

Table 1. Examples of novel plant traits engineered through RNAi.

Trait Target Gene Host Application
Enhanced
nutrient content
Lyc Tomato Increased concentration of lycopene (carotenoid antioxidant)
DET1 Tomato Higher flavonoid and b-carotene contents
SBEII Wheat, Sweet potato, Maize Increased levels of amylose for glycemic management and digestive health
FAD2 Canola, Peanut, Cotton Increased oleic acid content
SAD1 Cotton Increased stearic acid content
ZLKR/SDH Maize Lysine-fortified maize
Reduced alkaloid production CaMXMT1 Coffee Decaffeinated coffee
COR Opium poppy Production of non-narcotic alkaloid, instead of morphine
CYP82E4 Tobacco Reduced levels of the carcinogen nornicotine in cured leaves
Heavy metal
accumulation
ACR2 Arabidopsis Arsenic hyperaccumulation for phytoremediation
Reduced polyphenol
production
s-cadinene synthase gene Cotton Lower gossypol levels in cottonseeds, for safe consumption
Ethylene
sensitivity
LeETR4 Tomato Early ripening tomatoes
ACC oxidase gene Tomato Longer shelf life because of slow ripening
Reduced
allergenicity
Arah2 Peanut Allergen-free peanuts
Lolp1, Lolp2 Ryegrass Hypo-allergenic ryegrass
Reduced production of lachrymatory factor synthase lachrymatory factor synthase gene Onion "Tearless" onion

 

Prospects for RNAi

With RNAi, it would be possible to target multiple genes for silencing using a thoroughly-designed single transformation construct. Moreover, RNAi can also provide broad-spectrum resistance against pathogens with high degree of variability, like viruses9. Recent studies have hinted possible roles of RNAi-related processes in plant stress adaptation.

Although much progress has been made on the field of RNAi over the past few years, the full potential of RNAi for crop improvement remains to be realized.  The complexities of RNAi pathway, the molecular machineries, and how it relates to plant development are still to be elucidated.


References:

  1. Tang G. et al. (2007) Metabolomics 3:357-369
  2. Novina C.D. and Sharp P.A. (2004) Nature 430:161-164
  3. Napoli C. et al. (1990) Plant Cell 4: 279-289
  4. Fire A. et al. (1998) Nature 391: 806-811
  5. Fritz J.S. et al. (2006) Science STKE 339: 27
  6. Gupta P.K. (2006) Current Science 91:1443-1446
  7. Mansoor S. et al. (2006) Trends in Plant Science 11:559-565
  8. Qu J. et al. (2007) Journal of Virology 81: 6690-6699
  9. Huang G. et al. (2006) PNAS 103: 14302-1406
  10. Mao Y. (2007) Science 25: 1307-1313
  11. Baum J.A. (2007) Nature Biotechnology 25:1322-1326
  12. Nawaz-Ul-Rehman M.S. et al. (2007) Molecular Biotechnology 36: 159-165
  13. Sandhu A.S. et al. (2007) PNAS 104: 1766-1770
  14. Matthew L (2004) Comparative and Functional Genomics 5: 240-244
  15. Sato F. (2005) Plant Biotechnology 22: 431-442
  16. Burch-Smith T.M. et al. (2004) The Plant Journal 39:734-746
  17. Kusaba M. et al. (2003) Plant Cell 15: 1455-1467

 

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