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Printable Handouts
Navigable Slide Index
- Introduction
- HIV life cycle
- Typical course of HIV infection
- Why do we need new HIV drugs?
- Major goals of anti-HIV therapies
- Combinatorial RNA based therapy for HIV
- Applying RNAi for treatment of human diseases
- Treat HIV by systemic delivery of small RNAs
- Aptamers
- SELEX process
- Aptamer- siRNA treatment of HIV infection
- Features of aptamers
- Chimeric siRNA aptamer uptake
- Uptake of anti-gp120 aptamer by HIV infected cells
- Anti-gp120 uptake results
- Aptamer-targeted RNAi for HIV1 therapy
- Aptamer mediated inhibition of HIV2
- Small animal model for studying anti HIV RNAi
- In vivo testing of aptamer-siRNA chimera
- Aptamer and aptamer chimera inhibit HIV infection
- siRNA enhances duration of anti-HIV activity
- RACE PCR reaction
- Aptamer and siRNA prevent CD4+ cell decline
- Modular chemical aptamer synthesis
- Aptamer-stick-cocktailed siRNA effects on Tat/rev
- Aptamer and dsiRNAS effect on viral load
- Aptamer delivery of cytotoxic siRNAs
- Summary of aptamer studies
- Flexible PAMAM dendrimers
- Dendrimers protect siRNA from degradation
- G5 Dendrimer down regulate target mRNAs in vitro
- G5 dendrimer-Cy5 siRNA complexes distribution
- Multiplex siRNAs for HIV1 treatment
- Analyses of G5 dendrimer delivered siRNAs
- Rag2-/-gamma-c-/- mice (RAG-hu) experiments
- Targeted mRNA reductions in treated animals
- HIV loadsdrop post dendrimer siRNA injections
- Dendrimer/siRNA complexes and CD4 cell loss
- Bio distribution of G5 dendrimer siRNAs
- No type one IFN induction or liver toxicities
- Summary of dendrimer studies
- Acknowledgments
Topics Covered
- Systemic RNA interference (RNAi): Therapeutics for the treatment of HIV-1
- HIV life cycle
- Typical Course of HIV infection
- Why do we need new HIV drugs?
- Major goals of anti-HIV therapies
- Combinatorial RNA based therapy for HIV
- Applying RNAi for the treatment of human diseases
- treat HIV infection by systemic delivery of small RNAs
- Aptamers
- Chimeric-siRNA aptamer uptake into gp120 expressing cells
- Aptamer-targeted RNA interference for HIV-1 therapy
- Aptamer and aptamer chimera mediated inhibition of HIV-1
- Small animal model for studying anti-HIV RNAi based therapies
- Both aptamer and aptamer chimera inhibit HIV infection -Aptamer and chimeric aptamer-siRNA prevent CD4+ cell decline
- Aptamer and dsiRNAS effect on viral load
- Flexible PAMAM dendrimers with a triethanolamine core
- Dendrimers plus siRNAs form nanoparticles, protect siRNA from degradation and deliver siRNAs to T-lymphocytes
- G5 dendrimer delivered siRNAs down regulate target mRNAs in vitro
- Multiplex siRNAs for HIV-1 treatment
- In vivo analyses of G5 dendrimer delivered siRNAs
- Reductions in HIV loads following dendrimer siRNA injections
- Dendrimer-siRNA complexes protect HIV infected RAG-hu mice from CD4 T cell loss
- Bio distribution of G5 dendrimer siRNAs
Links
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Therapeutic Areas:
Talk Citation
Rossi, J. (2020, July 16). Systemic RNA interference (RNAi) therapeutics for the treatment of HIV-1 [Video file]. In The Biomedical & Life Sciences Collection, Henry Stewart Talks. Retrieved December 27, 2024, from https://doi.org/10.69645/HMEE6885.Export Citation (RIS)
Publication History
Financial Disclosures
- Professor John Rossi is a cofounder of MiNA Therapeutics.
Systemic RNA interference (RNAi) therapeutics for the treatment of HIV-1
A selection of talks on Infectious Diseases
Transcript
Please wait while the transcript is being prepared...
0:00
Hello, my name is John Rossi,
and I am going to be presenting a
talk on systemic RNA interference
therapeutics for the
treatment of HIV-1 infection.
In particular, I'm
going to be focusing
on two different methodologies that
we have developed over the past two
years for delivering smaller
interfering RNAs, the target
either HIV itself
or host factors that
are necessary for HIV replication.
These are RNA aptamers and
PAMAM flexible dendrimers.
0:28
This next slide
depicts HIV life cycle.
And beginning from the top and
working our way through the middle
of the slide, you can see that
HIV is an envelope virus, which it
interacts with primarily memory
T cells by the CD4 receptor
and one of two different
chemokine receptors,
one called CCR5 and the
other one called CXCR4.
The interaction is via the gp 120
HIV envelope protein, which then
allows the virus to be
internalized into the host cell,
were the viral RNA
is converted to DNA.
The DNA then in its
double stranded form
migrates to the nucleus of the cell.
There it integrates via the HIV
encoded integrase in several host
enzymes into those chromosome.
And then once that
cell is activated,
the HIV LPR, which is
the promoter region,
is used for
transcriptional initiation.
Driving first fully
spliced RNAs that encode
the regulatory proteins tat/rev,
both necessary for early events
in the viral life cycle.
Once the amount of protein
builds up to a sufficient level,
it blocks splicing.
Allowing unspliced messenger
RNAs to traffic for the nucleus
to the cytoplasm.
And then following translation
of the structural proteins,
the gag on M proteins,
and then subsequently
budding of the virus when it
encapsulates the full length
unspliced RNA.
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