viral (and other) techniques in gene therapy for hypertension
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Viral (and other) techniques in gene therapy for hypertension. Justin Grobe Oral Qualifying Exam and Dissertation Work Proposal. Hypertension. 50 million (1 in 5) Americans age 6 and older have high blood pressure (> 140/90 mmHg) and/or are taking antihypertensive medicine - PowerPoint PPT PresentationTRANSCRIPT
Viral (and other) techniques in gene therapy for hypertension
Justin GrobeOral Qualifying Exam
andDissertation Work Proposal
Hypertension50 million (1 in 5) Americans age 6 and older have high blood pressure (> 140/90 mmHg) and/or are taking antihypertensive medicine 90-95% of primary hypertension cases are idiopathicEducation and income levels are negatively correlated with blood pressure (affordability of treatment?)
American Heart Association. 2002 Heart and Stroke Statistical Update. Dallas, TX: American Heart Association, 2001.
Current therapies for hypertensionDiuretics
Thiazide Diuretics [Chlorothiazide, Hydrochlorothiazide]
Loop Diuretics [Furosemide]
Potassium-Sparing Diuretics [Spironolactone]
Stringer, J. L. Basic Concepts in Pharmacology, 2nd ed. McGraw-Hill Medical Publishing Division, New York. 2001.
Current therapies for hypertensionPeripheral Resistance Reducers
Direct Vasodilators Calcium Channel Blockers [Diltiazem, Nifedipine, Verapamil] Nitrates [Nitroglycerin, Nitroprusside] Others [Hydralazine, Minoxidil]
Sympathetic Nervous System Depressants Alpha-1 Blockers [Prazosin] Beta-(1 and 2) Blockers [Propranolol] Alpha-2 Agonists [Clonidine]
Stringer, J. L. Basic Concepts in Pharmacology, 2nd ed. McGraw-Hill Medical Publishing Division, New York. 2001.
Current therapies for hypertensionRenin-Angiotensin System Interference
Angiotensin Converting Enzyme (ACE) inhibitors [Captopril, Enalapril]
Angiotensin II (type 1) receptor blockers (“ARB’s”) [Losartan]
Stringer, J. L. Basic Concepts in Pharmacology, 2nd ed. McGraw-Hill Medical Publishing Division, New York. 2001.
Problems with conventional methodsOf those with hypertension,
31.6% are unaware27.4% are on medication and have it controlled26.2% are on medication but do not have it controlled14.8% are aware but are not on medication
American Heart Association. 2002 Heart and Stroke Statistical Update. Dallas, TX: American Heart Association, 2001.
JM Mallion, D Schmitt. Patient complaince in the treatment of arterial hypertension. Journal of Hypertension. 19(12): 2281-2283. 2001.
Issues of complianceCost, availability, understanding
Unaware
Medicated,Controlled
Medicated,Not Controlled
Aware,No Meds
Potential solution: Gene therapy
Ideally,Single treatment, once in lifetime of patient (a “cure”)
100% compliance, since no behavior is required
Cost / Availability would favor treatment for poor and/or uneducated individuals by their health care providers
Genetic therapy delivery methodsPhysical
“Molecular” (Non-viral)
Viral
Physical methods“Gene-gun” method
Used for plant research (only!)Plasmid-coated superfine beads fired from a .22 caliber chamberHighly inaccurate and inefficient (kills most cells)
Non-viral, “molecular” methodsLiposomes and naked DNAElectroporation methodSalt-shock methods (CaCl2)
Harsh, non-specific, (usually transient), can be inefficient
Agrobacterium tumefaciens “Ti-plasmid” methodUsed in plants (dicots only)
Viral methodsMany virus types available with varying:
Target specifictyDividing/Non-dividing cellsCassette sizeTransfection stabilityGenome insertion areasGerm-line/Somatic cellsEfficiency
Common virus types for gene therapy
AdenovirusAdeno-associated viruses (“AAV”)RetrovirusesLentivirusesHelper-dependent AAV
AdenovirusNon-enveloped, linear ds-DNAInfect dividing and non-dividing cells (good)High titers possible during production (good)Do not integrate into host genome well (bad)
The Adeno-Associated VirusSmall ss-DNANot much immune response (very good!)Infects both dividing and non-dividing cells (good)Somewhat difficult to produce at high titers (bad)Very small cassette – 3 kb (bad?)Integration into host genome specifically into an “unimportant” portion of chromosome 19 (very very good!)
RetrovirusRNA, depend on viral enzymesIntegrates into genome (good), but in very random positions (potentially very bad – cancer!)Only infects dividing cells (bad?)Difficult to obtain high titers in production (bad), but easy to make large volumes (good)Large cassette sizes possible (very good)
LentivirusSub-family of retroviruses (HIV family)
Same traits of retroviruses, EXCEPT: Ability to transduce non-dividing cells (very good!) High titers possible in production (good) Large scale production yields small volume (bad) Animal care and use issues (because of HIV origins)
Helper-dependent AAV
Very newVery secret (patent restrictions)Most of the same characteristics as AAV, except;HUGE PAYLOAD CASSETE SIZE - 30 to 60 kb
Practical Challenges with VirusesSafety
ToxicityImmune reactionsIntegration – Position and genomic effects
EfficacyControl of transgene expression
Ethical ChallengesQuestionable need, considering the risks?Regulation of transgene?Population genetics and eugenics?
Practical and Ethical Challenge: Transgene Control
One approach: tetracycline-regulatable systemsTet-OFF (rTA)
Constitutive rTA protein expression (blocks transcription) Presence of a tetracycline (doxycycline has low side-
effects) causes release of the rTA suppressive protein from the tet-operator, allows transcription of transgene
Strong promoter (tissue specific?) rTA
rTA
Tet-operator PromoterTransgene of
interest
(Without tetracycline)
(With tetracycline)
Practical and Ethical Challenge: Transgene Control
Tet-ON (rtTA) Constitutive rtTA protein expression (transcription factor) Presence of tetracycline causes binding of rtTA to
operator, inducing transcription Small amout of leak usually observed in absence of
tetracyclines
Strong promoter (tissue specific?) rtTA
rtTA
Tet-operator PromoterTransgene of
interest
(With tetracycline)
(Without tetracycline)
Practical and Ethical Challenge: Transgene Control
New generations of the tetracycline-regulatable systems incorporate both tet-ON and tet-OFF, and new tet-Silencer sequences
Even tighter control over transgene“Off” is really off
Together:Hypertension therapy needs a new directionGene therapy may be that directionThe lentiviruses allow large transgene cassettes to be stably transfected in vivo Larger cassette sizes allow for incorporation of transcriptional control systems, overcoming the practical and ethical dilemma of transgene controlThe tetracycline-regulatable systems are examples of such transcriptional control systems
Research hypothesisAn anti-hypertensive therapeutic gene, delivered via a Lenti-based viral vector, and under the control of a tetracycline-sensitive promoter system, will alleviate hypertension and reverse hypertension-associated end-organ damage in a regulatable manner
Regulating gene therapy for hypertension: proposed project plan
Clone tet-system and therapeutic genesProduce viruses containing system Establish transgene control with reporter genes
In vitroIn vivo
Induce therapeutic genesReverse hypertension in vivoReverse end-organ damage in vivo
Hypertension target genes: the RAS
Angiotensinogen
Angiotensin II
Angiotensin I
AT1R AT2R
Renin
ACE, Chymase
tPA Angiotensin (1-9)
Angiotensin (1-7)
Mas / (AT1-7R?)
ACE
ACE2
ACE2
Endopeptidases
Hypertension target genes: Angiotensinogen
Angiotensinogen
Angiotensin (1-9)
Angiotensin II
Angiotensin I
Angiotensin (1-7)
AT1R AT2R Mas / (AT1-7R?)
Renin
ACE, Chymase ACE
ACE2
ACE2
tPA
Endopeptidases
Hypertension target genes: ACE2
Angiotensinogen
Angiotensin (1-9)
Angiotensin II
Angiotensin I
Angiotensin (1-7)
AT1R AT2R Mas / (AT1-7R?)
Renin
ACE, Chymase ACE
ACE2
ACE2
tPA
Endopeptidases
ReporterViral Constructs: single vector
EF1a - elongation factor 1 alphartTA - “Tet-ON”IRES - internal ribosome entry sitetTS - tet-silencerTRE - tetracycline responsive elementPLAP - placental alkaline phosphatase
rtTA IRES tTSEF1a PLAPTRE poly A
(+ Dox)
Single vector effectsIn vitro titer:
No virus - 0 cells/mLVirus, no Dox - 1.98x106
Virus, Dox - 1.15x107 (6x induction)
In vivo staining:No staining in heart, liver, lung of any animal
ReporterViral Constructs: two vectors
EF1a - elongation factor 1 alphartTA - “Tet-ON”IRES - internal ribosome entry sitetTS - tet-silencerTRE - tetracycline responsive elementSEAP - secreted alkaline phosphatase
SEAPTRE poly A
rtTA IRES tTSEF1a poly A
(+ Dox)
Two vectors in vitro
60
70
80
90
100
110
120
130
140
TRE-SEAP EF1a-rtTA-IRES-tTSand TRE-SEAP
Lu
min
esce
nce
(R
LU
)
No Doxycycline
(1 ug/uL) Doxycycline
(Detection Limit)
Two vectors in vivo:systemic delivery
No SEAP detected in blood of animals with or without doxycycline-induction
Basal, 2 days, 7 days, 12 days, 17 daysSubcutaneous injection, ad. lib. in drinking water
ProblemsNo positive control group - assay?Systemic delivery & simple probability - design?
Two vectors in vivo:plans for local delivery
To increase probability of infection by both vectors in same target cells, reduce total number of target cells
Antisense to angiotensinogen - hepatic-portal injectionACE2 - any tissue (skeletal muscle?)
Current workRT-PCR of systemic two-vector animal tissues (heart, liver) to measure rtTA and SEAP transcriptsCloning positive control for SEAP (EF1a - SEAP)Working on making transgenic rat which expresses rtTA and tTS proteins constituitively and ubiquitouslyProducing three viruses
EF1a-SEAPEF1a-rtTA-IRES-tTSTRE-SEAP
Future plansIn vivo reporter gene experiment with local delivery and positive control groupClone therapeutic gene into TYF-TRE plasmid (“second vector”)Produce virusesIn vivo blood pressure and end-organ damage experiments
HypertrophyVascular Reactivity