Sage Journals: Discover world-class research

Abstract

Background:

Dendrimers are an attractive alternative to viral vectors due to the low cost of production, larger genetic insert-carrying capacity, and added control over immune- and genotoxic complications through versatile functionalization. However, their transfection rates pale in comparison to their viral counterparts, resulting in widespread research efforts in the attempt to improve transfection efficiency.

Materials and Methods:

In this work, we designed a synthetic diblock nuclear-localization sequence peptide (NLS) (DDDDDDVKRKKKP) and complexed it with polyamidoamine (PAMAM) dendrimer G4 to form a duplex for gene delivery. We conducted transmission electron microscopy, gel mobility shift assay, and intracellular trafficking studies. We also assessed its transfection efficiency for the delivery of a green fluorescent protein-encoding plasmid (pGFP) to NIH3T3 cells.

Results:

PAMAM dendrimer G4, NLS, and plasmid DNA can form a stable three-part polyplex and gain enhanced entry into the nucleus. We found transfection efficiency, in large part, depends on the ratio of G4:NLS:plasmid. The triplex prepared at the ratio of 1:60:1 for G4:NLS:pGFP has been shown to be more significantly efficient in transfecting cells than the control group (G4/pGFP, 0.5:1).

Conclusions:

This new diblock NLS peptide can facilely complex with dendrimers to improve dendrimer-based gene transfection. It can also complex with other polycationic polymers to produce more potent nonviral duplex gene delivery vehicles.

Get full access to this article

View all access options for this article.

References

Jarrett

, Lee

, Yeh

Y-H

, et al. Somatic genome editing with CRISPR/Cas9 generates and corrects a metabolic disease. Sci Rep, 2017; 7:44624.

Beltran

, Cideciyan

, Boye

, et al. Optimization of retinal gene therapy for X-linked retinitis pigmentosa due to RPGR mutations. Mol Ther, 2017; 25:1866–1880.

Chen

, Gao

, Yuan

, et al. Oncolytic adenovirus complexes coated with lipids and calcium phosphate for cancer gene therapy. ACS Nano, 2016; 10:11548–11560.

Mehier-Humbert

, Guy

. Physical methods for gene transfer: Improving the kinetics of gene delivery into cells. Adv Drug Deliv Rev, 2005; 57:733–753.

Yin

, Kanasty

, Eltoukhy

, et al. Non-viral vectors for gene-based therapy. Nat Rev Genet, 2014; 15:541–555.

Iizuka

, Sakurai

, Tachibana

, et al. Neonatal gene therapy for hemophilia B by a novel adenovirus vector showing reduced leaky expression of viral genes. Mol Ther Methods Clin Dev, 2017; 6:183–193.

Wang

, Tai

PWL

, Gao

. Adeno-associated virus vector as a platform for gene therapy delivery. Nat Rev Drug Dis, 2019; 18:358–378.

Kurosaki

, Uchibori

, Mato

, et al. Optimization of adeno-associated virus vector-mediated gene transfer to the respiratory tract. Gene Ther, 2017; 24:290–297.

Campochiaro

, Lauer

, Sohn

, et al. Lentiviral vector gene transfer of endostatin/angiostatin for macular degeneration (GEM) study. Hum Gene Ther, 2017; 28:99–111.

10.

Elsner

, Bohne

. The retroviral vector family: Something for everyone. Virus Genes, 2017; 53:714–722.

11.

Lundstrom

. Viral vectors in gene therapy. Diseases, 2018; 6:42.

12.

David

, Doherty

. Viral vectors: The road to reducing genotoxicity. Toxicol Sci, 2017; 155:315–325.

13.

Ramamoorth

, Narvekar

. Non viral vectors in gene therapy—An overview. J Clin Diagn Res, 2015; 9:GE1–GE6.

14.

Nam

, Nam

, Lee

, et al. Dendrimer type bio-reducible polymer for efficient gene delivery. J Control Release, 2012; 160:592–600.

15.

Dong

, Su

, Yu

, et al. A redox-responsive cationic supramolecular polymer constructed from small molecules as a promising gene vector. Chem Commun, 2013; 49:9845–9847.

16.

, He

, Li

, et al. A novel polymer-lipid hybrid nanoparticle for efficient nonviral gene delivery. Acta Pharmacol Sin, 2010; 31:509–514.

17.

Zhang

, Xu

, Wang

, et al. Cationic compounds used in lipoplexes and polyplexes for gene delivery. J Control Release, 2004; 100:165–180.

18.

Chen

, McCrate

, Lee

JCM

, et al. The role of surface charge on the uptake and biocompatibility of hydroxyapatite nanoparticles with osteoblast cells. Nanotechnology, 2011; 22:105708.

19.

Bus

, Traeger

, Schubert

. The great escape: How cationic polyplexes overcome the endosomal barrier. J Mater Chem B, 2018; 6:6904–6918.

20.

Dandekar

, Jain

, Keil

, et al. Cellular delivery of polynucleotides by cationic cyclodextrin polyrotaxanes. J Control Release, 2012; 164:387–393.

21.

Wen

, Zheng

, Shen

, Shi

. Surface modification and PEGylation of branched polyethyleneimine for improved biocompatibility. J Appl Polym Sci, 2013; 128:3807–3813.

22.

Boas

, Heegaard

PMH

. Dendrimers in drug research. Chem Soc Rev, 2004; 33:43–63.

23.

Thibault

, Nimesh

, Lavertu

, et al. Intracellular trafficking and decondensation kinetics of chitosan-pDNA polyplexes. Mol Ther, 2010; 18:1787–1795.

24.

Won

, Yoon

, Lee

, et al. Poly(oligo-D-arginine) with internal disulfide linkages as a cytoplasm-sensitive carrier for siRNA delivery. Mol Ther, 2011; 19:372–380.

25.

Parelkar

, Letteri

, Chan-Seng

, et al. Polymer-peptide delivery platforms: Effect of oligopeptide orientation on polymer-based DNA delivery. Biomacromolecules, 2014; 15:1328–1336.

26.

Opanasopit

, Rojanarata

, Apirakaramwong

, et al. Nuclear localization signal peptides enhance transfection efficiency of chitosan/DNA complexes. Int J Pharm, 2009; 382:291–295.

27.

Branden

, Mohamed

, Smith

CIE

. A peptide nucleic acid-nuclear localization signal fusion that mediates nuclear transport of DNA. Nat Biotechnol, 1999; 17:784–787.

28.

Schneider

, Rasband

, Eliceiri

. NIH Image to ImageJ: 25 years of image analysis. Nat Methods, 2012; 9:671–675.

29.

Tang

, Szoka

. The influence of polymer structure on the interactions of cationic polymers with DNA and morphology of the resulting complexes. Gene Ther, 1997; 4:823–832.

30.

Lakshminarayanan

, Ravi

, Tatineni

, et al. Efficient dendrimer-DNA complexation and gene delivery vector properties of nitrogen-core poly(propyl ether imine) dendrimer in mammalian cells. Bioconjug Chem, 2013; 24:1612–1623.

31.

Braun

, Vetro

, Tomalia

, et al. Structure/function relationships of polyamidoamine/DNA dendrimers as gene delivery vehicles. J Pharm Sci, 2005; 94:423–436.

32.

Dobrovolskaia

, Patri

, Simak

, et al. Nanoparticle size and surface charge determine effects of PAMAM dendrimers on human platelets in vitro. Mol Pharm, 2012; 9:382–393.

33.

Ainalem

, Nylander

. DNA condensation using cationic dendrimers-morphology and supramolecular structure of formed aggregates. Soft Matter, 2011; 7:4577–4594.

34.

Yuan

, Yeudall

, Yang

. PEGylated polyamidoamine dendrimers with bis-aryl hydrazone linkages for enhanced gene delivery. Biomacromolecules, 2010; 11:1940–1947.

35.

Jevprasesphant

, Penny

, Jalal

, et al. The influence of surface modification on the cytotoxicity of PAMAM dendrimers. Int J Pharm, 2003; 252:263–266.

36.

Kuo

JHS

, Jan

, Chu

. Mechanism of cell death induced by cationic dendrimers in RAW 264.7 murine macrophage-like cells. J Pharm Pharmacol, 2005; 57:489–495.

37.

Huth

, Hoffmann

, von Gersdorff

, et al. Interaction of polyamine gene vectors with RNA leads to the dissociation of plasmid DNA-carrier complexes. J Gene Med, 2006; 8:1416–1424.

38.

Haensler

, Szoka

. Polyamidoamine cascade polymers mediate efficient transfection of cells in culture. Bioconjug Chem, 1993; 4:372–379.

39.

, Gao

, Tang

, et al. PEG-conjugated PAMAM dendrimers mediate efficient intramuscular gene expression. AAPS J, 2009; 11:395–405.

40.

Luong

, Kesharwani

, Deshmukh

, et al. PEGylated PAMAM dendrimers: Enhancing efficacy and mitigating toxicity for effective anticancer drug and gene delivery. Acta Biomater, 2016; 43:14–29.

41.

Kolhatkar

, Kitchens

, Swaan

, et al. Surface acetylation of polyamidoamine (PAMAM) dendrimers decreases cytotoxicity while maintaining membrane permeability. Bioconjug Chem, 2007; 18:2054–2060.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

0.00 MB

0.08 MB

Duplex of Polyamidoamine Dendrimer/Custom-Designed Nuclear-Localization Sequence Peptide for Enhanced Gene Delivery

Abstract

Background:

Materials and Methods:

Results:

Conclusions:

Get full access to this article

References

Supplementary Material