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An Introduction to RNAi
In Vivo
Performing RNAi Experiments in Animals
Gene silencing by RNA interference is being
used routinely to study gene function in cultured mammalian cells.
While this approach has been extremely powerful, it does not
allow a critical evaluation of how genes function within the
whole organism. To address this problem, researchers are now
applying RNAi in vivo. Although still in its early stages, use
of RNAi in vivo already shows promise and significant advances
have been made.
The Two Basic Methods
Two basic methods for triggering RNAi have
been adapted for use in vivo: delivery of siRNAs, and delivery
of plasmid and viral vectors that express a short hairpin RNA
(shRNA) that is subsequently processed into active siRNA. As
with the application of RNAi in cultured cells, use of siRNAs
is more prominent than use of shRNA expression vectors. For RNAi
experiments in cultured cells, effective siRNAs to a particular
target of interest are easier to obtain, and because they are
small and only need to cross the cell membrane and not the nuclear
membrane to be effective, they are easier to deliver. In contrast,
shRNA expression vectors are time consuming to construct, particularly
when one takes into account the time required to create and test
several shRNA sequences to find an effective one. siRNAs are
also easier to deliver than plasmid based shRNA expression vectors,
and they do not have the associated problems with insertional
mutagenesis and immunogenicity that plague retroviral (including
lentiviral) and adenoviral vectors, respectively.
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Figure
1. Strategies for Delivery of siRNA
Molecules In Vivo.
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The success of siRNA mediated gene silencing
in vivo depends on efficient delivery and retention of the siRNA
in the vasculature of a specific tissue of interest, and its
effective uptake by those cells. In addition, the siRNA must
remain stable until it can reach its ultimate destination. Although
early, there have been reports of success using both local and
systemic delivery of siRNAs.
Success with Local Administration
of siRNAs
Perhaps the greatest success has come with
local administration of siRNA to the eye. An siRNA to VEGF delivered
to the subretinal space in mice has been proven to reduce eye
angiogenesis [1]. In this model, there was no need to modify
the siRNA, or to complex it with lipid polymer or other delivery
agents, as has been necessary in some other systems. More recently,
an siRNA to VEGF, developed by Acuity Pharmaceuticals and designed
to be delivered via intravitreal injection, has entered phase
II clinical trials as a treatment for wet age-related macular
degeneration.
In rat models, modified siRNAs to the pain
related cation channel P2X3 have been successfully delivered
into the brains of rats via intrathecal infusion using surgically
implanted pumps; the siRNAs significantly inhibited the neuropathic
pain response in this model system [2]. Although not practical
for many researchers, this approach demonstrates that siRNAs
can be successfully delivered locally into the rodent brain,
and that in vivo functional genomics studies of CNS related genes
using siRNAs are possible.
There is considerable interest in delivering
siRNAs into the lung in the attempts to study pulmonary as well
as infectious diseases and to potentially treat influenza, SARS,
and other clinically relevant pulmonary diseases caused by RNA
viruses. In one promising study, an intranasal delivery system
was used in primates to deliver a SARS virus specific siRNA,
resulting in reduced fever, decreased viral load, and reduced
alveoli damage [3]. This study demonstrates the validity of intranasal
delivery of siRNAs to the lung.
Progress with Systemic siRNA Delivery
The feasibility of systemic in vivo siRNA delivery
in mammals was first demonstrated using hydrodynamic tail vein
injections† in mice. In this procedure, unmodified siRNAs are
rapidly injected into the tail vein in a large volume of aqueous
solution, resulting in localization within hepatocytes [3]. Although
not clinically relevant, this procedure does permit gene function
and drug target validation studies within the rodent liver, until
more effective delivery technologies are developed. In support
of this technique, Song and colleagues found that hydrodynamic
injection of a Fas siRNA resulted in silencing of Fas in mouse
hepatocytes for a period of 10 days. This treatment protected
hepatocytes from Fas antibody and concanavalin A stimulated apoptosis,
and protected mice from fulminant hepatitis [4]. Similarly, hydrodynamic
tail vein injection of a caspase 8 siRNA protected mice against
acute liver failure induced by Fas antibody or expression of
Fas ligand [5].
More recently, low volume, normal pressure
intravenous delivery of a modified siRNA targeting apolipoprotein
B in mice resulted in gene silencing in the liver and jejunum.
The siRNA was conjugated with cholesterol to provide targeted
delivery, and included backbone and sugar modifications to enhance
serum stability [6].
Systemic delivery of siRNAs will likely be
required to target most tumor types, as well as many other in
vivo targets. To this end, several groups are investigating the
use of lipid based and nanoparticle based siRNA delivery complexes
[7-10].
The work on systemic delivery of siRNAs illustrates
three obstacles that must be overcome for siRNA to be successful
in vivo: selective delivery into the desired tissue, adequate
protection from degradation en route to the target tissue, and
protection of the siRNA from rapid excretion. Surprisingly, rapid
excretion has proven to be more of a problem than in vivo stability
[11]. Although chemical stabilization is readily achieved via
siRNA modification, it does not appear to be necessary in most
cases, as excretion appears to occur prior to degradation. Use
of nanoparticles or lipid complexes currently shows more promise
than chemical modification to address the pharmacokinetics and
tissue distribution issues endemic to in vivo siRNA delivery.
Looking to the Future
RNAi is now firmly entrenched as an invaluable
tool in most drug discovery pipelines, and further advances in
the technology will no doubt enhance the utility of the technique
in identifying and validating potential drug targets in vivo.
In addition, siRNAs themselves have huge potential as therapeutic
agents. If realized, the impact on the pharmaceutical industry
would be revolutionary. The most significant hurdle for the therapeutic
use of siRNAs is how to provide targeted delivery. Although significant
progress has been made, delivery of nucleic acids to specific
organs, tissues, and cells will require additional advances,
including development of possible novel conjugations and/or formulations
to specifically target certain cells.
†In vivo hydrodynamic delivery of nucleic acids is covered by patents and patent applications of Mirus Bio Corporation, including U.S. Patents 6,627,616, 6,379,966 and 6,897,068 and related filings worldwide. Research and commercial uses by for-profit entities require a license--please see www.mirusbio.com for contact information.
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Ordering Information for Ambion Products:
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| Cat# |
Product Name |
Size |
| AM16230 |
Custom siRNA, In Vivo Ready |
100 nmol |
| AM16231 |
Custom siRNA, In Vivo Ready |
250 nmol |
| AM16232 |
Custom siRNA, In Vivo Ready |
1 µmol |
| AM16233 |
Custom siRNA, In Vivo Ready |
10 µmol |
| AM16830 |
Silencer® Pre-designed siRNA, In Vivo Ready |
100 nmol |
| AM16831 |
Silencer® Pre-designed siRNA, In Vivo Ready |
250 nmol |
| AM16832 |
Silencer® Pre-designed siRNA, In Vivo Ready |
1 µmol |
| AM16833 |
Silencer® Pre-designed siRNA, In Vivo Ready |
10 µmol |
| AM51340 |
Silencer® Validated siRNA, In Vivo Ready |
100 nmol |
| AM51341 |
Silencer® Validated siRNA, In Vivo Ready |
250 nmol |
| AM51342 |
Silencer® Validated siRNA, In Vivo Ready |
1 µmol |
| AM51343 |
Silencer® Validated siRNA, In Vivo Ready |
10 µmol |
| For Research Use Only. Not for use in diagnostic procedures. |
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| TechNotes
Archive |
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1. Reich SJ, Fosnot J, Kuroki A, Tang W,
Yang X, Maguire AM, Bennett J, Tolentino MJ (2003) Small interfering
RNA (siRNA) targeting VEGF effectively inhibits ocular neovascularization
in a mouse model. Mol Vis 9:210–6.
2. Dorn G, Patel S, Wotherspoon G, Hemmings-Mieszczak
M, Barclay J, Natt FJ, Martin P, Bevan S, Fox A, Ganju P, Wishart
W, Hall J (2004) siRNA relieves chronic neuropathic pain. Nucleic
Acids Res 32(5):e49.
3. Li BJ, Tang Q, Cheng D, Qin C, Xie
FY, Wei Q, Xu J, Liu Y, Zheng BJ, Woodle MC, Zhong N, Lu PY (2005) Using siRNA in prophylactic and therapeutic
regimens against SARS coronavirus in Rhesus macaque. Nat Med 11(9):944–51.
4. Song E, Lee SK, Wang J, Ince N, Ouyang
N, Min J, Chen J, Shankar P, Lieberman J (2003) RNA interference
targeting Fas protects mice from fulminant hepatitis. Nat
Med 9(3):347–51.
5. Zender L, Hutker S, Liedtke C, Tillmann
HL, Zender S, Mundt B,
Waltemathe M, Gosling T, Flemming P, Malek NP, Trautwein C, Manns MP, Kuhnel
F, Kubicka S (2003) Caspase 8 small interfering RNA prevents acute liver failure
in mice. Proc Natl Acad Sci USA 100(13):7797–802.
6. Soutschek J, Akinc A, Bramlage B, Charisse
K, Constien R, Donoghue M, Elbashir S, Geick A, Hadwiger P, Harborth
J, John M, Kesavan V, Lavine G, Pandey RK, Racie T, Rajeev KG, Rohl I, Toudjarska I, Wang G, Wuschko S, Bumcrot D, Koteliansky V, Limmer S, Manoharan M, Vornlocher HP (2004) Therapeutic silencing of an endogenous gene
by systemic administration of modified siRNAs. Nature 432(7014):173–8.
7. Urban-Klein B, Werth S, Abuharbeid S,
Czubayko F, Aigner A (2005) RNAi-mediated gene-targeting through
systemic application of polyethylenimine (PEI)-complexed siRNA
in vivo. Gene Ther 12(5):461–6.
8. Pal A, Ahmad A, Khan S, Sakabe I, Zhang
C, Kasid UN, Ahmad I (2005) Systemic delivery of Raf siRNA using cationic cardiolipin liposomes
silences Raf-1 expression and inhibits tumor growth in xenograft model of human
prostate cancer. Int J Oncol 26(4):1087–91.
9. Morrissey DV, Lockridge JA, Shaw
L, Blanchard K, Jensen K, Breen W, Hartsough K, Machemer L, Radka
S, Jadhav V, Vaish N, Zinnen S, Vargeese C, Bowman K, Shaffer
CS, Jeffs LB, Judge A, MacLachlan I, Polisky B (2005) Potent
and persistent in vivo anti-HBV activity of chemically modified
siRNAs. Nat Biotechnol 23(8):1002–7.
10. Schiffelers RM, Ansari A, Xu J, Zhou
Q, Tang Q, Storm G, Molema G, Lu PY, Scaria PV, Woodle MC (2004) Cancer siRNA therapy by tumor selective
delivery with ligand-targeted sterically stabilized nanoparticle. Nucleic
Acids Res 32(19):e149.
11. Lu PY, Xie F, Woodle MC (2005) In vivo
application of RNA interference: from functional genomics to
therapeutics. Adv Genet 54:117–42.
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NEW!
Silencer® In Vivo Ready siRNAs
To support the growing use of siRNAs in
vivo, Ambion now provides a new grade of siRNAs called Silencer® In
Vivo Ready siRNAs that are specifically for
research use in animals. These siRNAs feature:
• Convenient 100, 250, and 1000 nmol
sizes; larger sizes available upon request
• HPLC purified to >95% purity
• Free of harmful salts
• Endotoxin tested
To help you get started with experiments
in vivo, Ambion has created the In
Vivo siRNA Resource. Here, we provide protocols, important
references, and the latest information to help you succeed with
in vivo delivery of siRNA.
All of Ambion's Silencer Pre-designed,
Validated, and Control siRNAs are available in this new format.
Of course you can also provide your own siRNA sequence. |
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In Vivo siRNA Resource
[read]
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RNA Interference Resource
[read]
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siRNA Design: It's All in the Algorithm
[read]
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Superior Gene Silencing Using Adenoviral Vectors
[read]
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