Targeting recombinant adeno-associated virus vectors to enhance gene transfer to pancreatic islets and liver

Loiler, Scott A.; Conlon, Thomas J.; Song, Sihong; Tang, Qiushi; Warrington, Kenneth H.; Agarwal, Anupam; Kapturczak, Matthias H.; Li, Chengwen; Ricordi, Camillo; Atkinson, M. A.; Muzyczka, Nicholas; Flotte, Terence R.

doi:10.1038/sj.gt.3302046

Cited by 97 publications

(61 citation statements)

References 34 publications

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“…25,26 For comparison to the rAAV8 results, we also placed the G6Pase-a gene in AAV1-G6Pase-a under the chicken b-actin promoter/CMV enhancer. In all, 12 G6Pase-a À/À mice were infused neonatally with 5 Â 10 11 particles of AAV1-G6Pase-a (AAV1-G6Pase-a-1X).…”

Section: Resultsmentioning

confidence: 99%

Long-term correction of murine glycogen storage disease type Ia by recombinant adeno-associated virus-1-mediated gene transfer

Ghosh

et al. 2005

Gene Ther

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Glycogen storage disease type Ia (GSD-Ia) is caused by a deficiency in glucose-6-phosphatase-a (G6Pase-a), a ninetransmembrane domain, endoplasmic reticulum-associated protein expressed primarily in the liver and kidney. Previously, we showed that infusion of an adeno-associated virus (AAV) serotype 2 vector carrying murine G6Pase-a (AAV2-G6Pase-a) into neonatal GSD-Ia mice failed to sustain their life beyond weaning. We now show that neonatal infusion of GSD-Ia mice with an AAV serotype 1-G6Pase-a (AAV1-G6Pase-a) or AAV serotype 8-G6Pase-a (AAV8-G6Pase-a) results in hepatic expression of the G6Pase-a transgene and markedly improves the survival of the mice. However, only AAV1-G6Pase-a can achieve significant renal transgene expression. A more effective strategy, in which a neonatal AAV1-G6Pase-a infusion is followed by a second infusion at age 1 week, provides sustained expression of a complete, functional, G6Pase-a system in both the liver and kidney and corrects the metabolic abnormalities in GSD-Ia mice for the 57 week length of the study. This effective use of gene therapy to correct metabolic imbalances and disease progression in GSD-Ia mice holds promise for the future of gene therapy in humans. Gene Therapy (2005) 13, 321-329.

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Section: Resultsmentioning

confidence: 99%

Long-term correction of murine glycogen storage disease type Ia by recombinant adeno-associated virus-1-mediated gene transfer

Ghosh

et al. 2005

Gene Ther

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“…Genetic modification of the AAV2 capsid by oligonucleotide insertions, random mutagenesis or DNA shuffling is able to circumvent some of these limitations. [8][9][10][17][18][19] Whereas larger peptides up to the size of GFP (238 amino acids) could be accommodated at the VP2 N-terminus 15,[20][21][22][23][24][25] the addition of small peptides up to 34 amino acids is tolerated at several positions of the AAV2 capsid. 1 Among the tolerated insertion sites for small peptides, insertions in the AAV2 heparin binding domain 26,27 adjacent to amino acids 587 or 588 was most successful.…”

Section: Introductionmentioning

confidence: 99%

Heart-targeted adeno-associated viral vectors selected by in vivo biopanning of a random viral display peptide library

et al. 2010

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Selection of targeted vectors from virus display peptide libraries is a versatile and efficient approach to improve vector specificity and efficiency. This strategy has been used to target various cell types in vitro. Here, we report the screening of an adeno-associated virus type 2 (AAV2) display peptide library in vivo to select vectors specifically homing to heart tissue after systemic application in mice. Selected library clones indicated superior specificity of gene transfer compared with wild-type AAV2, AAV9 and a heparin binding-deficient AAV2 mutant. Such targeted vectors were able to reconstitute expression of d-sarcoglycan in the heart of adult d-sarcoglycan knockout mice after systemic gene transfer in vivo, attesting to the therapeutic potential of this approach.

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“…Insertion after position 138 of the 28-amino acid ApoE-derived ligand led to a 90-fold increase in pancreatic islet cells in-vitro transduction. Additionally, a four-fold increase of human antitrypsin expression was observed compared to unmodified AAV vector transduction (Loiler et al, 2003). Viral dose can be reduced 100-fold with similar transduction results as a consequence of ApoE-derived ligand insertion with a critical impact on side effect reduction.…”

Section: Targeting By Ligand Insertionmentioning

confidence: 88%

“…For AAV2-derived vectors, peptides inserted in positions 1, 34, 138, 161, 459, 584, 587 and 588 (relative to VP1 start codon) are displayed on the vector surface, and allow production of vectors with similar viral titers to those observed for unmodified AAV2 vectors (Shi et al, 2001;Wu et al, 2000b). Most of the studies have used positions 138 (VP2 N-terminal), 587 and 588 (HSPG binding domain) to insert peptides ranging from 5 to 272 amino acids (Loiler et al, 2003;Nicklin et al, 2001a;Perabo et al, 2006;Shi et al, 2001;White et al, 2007;White et al, 2004;Wu et al, 2000b;Yu et al, 2009). Capsid protein modifications have improved gene delivery to lung (Kwon & Schaffer, 2008), endothelial cells (Nicklin et al, 2001a), pancreatic islets (Loiler et al, 2003), vascular tissue (White et al, 2004), atherosclerotic lesions (White et al, 2007), muscle (Yu et al, 2009), myocardium (Yang et al, 2009), and cancer cells .…”

Section: Targeting By Ligand Insertionmentioning

confidence: 99%

Gene Delivery Systems: Tailoring Vectors to Reach Specific Tissues

Alméciga-Díaz¹,

Cuaspa²,

Barrera³

2011

Non-Viral Gene Therapy

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Targeting recombinant adeno-associated virus vectors to enhance gene transfer to pancreatic islets and liver

Cited by 97 publications

References 34 publications

Long-term correction of murine glycogen storage disease type Ia by recombinant adeno-associated virus-1-mediated gene transfer

Long-term correction of murine glycogen storage disease type Ia by recombinant adeno-associated virus-1-mediated gene transfer

Heart-targeted adeno-associated viral vectors selected by in vivo biopanning of a random viral display peptide library

Gene Delivery Systems: Tailoring Vectors to Reach Specific Tissues

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