Efficient Gene Delivery Vectors Research Articles

Multiplexed Cre-dependent selection yields systemic AAVs for targeting distinct brain cell types.

Recombinant adeno-associated viruses (rAAVs) are efficient, non-invasive gene delivery vectors via intravenous delivery, however, natural serotypes display a finite set of tropisms. To expand their utility, we evolved AAV capsids to efficiently transduce specific cell types in adult mouse brains. Building upon our previous Cre recombination-based AAV targeted evolution (CREATE) platform, we developed Multiplexed-CREATE (M-CREATE) to quickly and accurately identify variants of interest in a given selection landscape through multiple positive and negative selection criteria by incorporating next-generation sequencing, synthetic library generation, and a novel analysis pipeline. In vivo selections for brain endothelial cell-, astrocyte-, and neuron-transducing capsids have identified variants that can transduce the central nervous system broadly, exhibit bias toward vascular cells and astrocytes, target neurons with greater specificity, or cross the blood-brain barrier across diverse murine strains. Collectively, M-CREATE methodology accelerates the discovery of novel capsids for use in neuroscience and gene therapy applications.

Amino Acid-Linked Low Molecular Weight Polyethylenimine for Improved Gene Delivery and Biocompatibility.

The construction of efficient and low toxic non-viral gene delivery vectors is of great significance for gene therapy. Herein, two novel polycations were constructed via Michael addition from low molecular weight polyethylenimine (PEI) 600 Da and amino acid-containing linkages. Lysine and histidine were introduced for the purpose of improved DNA binding and pH buffering capacity, respectively. The ester bonds afforded the polymer biodegradability, which was confirmed by the gel permeation chromatography (GPC) measurement. The polymers could well condense DNA into nanoparticles and protect DNA from degradation by nuclease. Compared with PEI 25 kDa, these polymers showed higher transfection efficiency, lower toxicity, and better serum tolerance. Study of this mechanism revealed that the polyplexes enter the cells mainly through caveolae-mediated endocytosis pathway; this, together with their biodegradability, facilitates the internalization of polyplexes and the release of DNA. The results reveal that the amino acid-linked low molecular weight PEI polymers could serve as promising candidates for non-viral gene delivery.

Lentiviral interferon with immune checkpoint blockade: A novel method for gene therapy in bladder cancer.

33 Background: Gene therapy for bladder cancer (BLCA) is rapidly evolving. We reported that intravesical adenoviral interferon-alpha (Ad-IFNα) produced a complete response in 35% of patients with BCG-unresponsive BLCA enrolled in a Phase II trial. Lentivirus (LV) is another potential vector for intravesical delivery of IFNα. LV can infect non-dividing cells and integrate into the host’s genome, making it more efficient gene delivery vectors. As treatment with IFN upregulates checkpoint inhibitors, we also wanted to investigate the role of checkpoint inhibitors with and without IFN gene therapy. Methods: Murine BLCA cell lines were transduced in-vitro with LV-IFNα (MOI 2:1). IFNα levels were measured by ELISA. Cell viability was assessed using Trypan blue dye exclusion. qPCR was used to identify expression of IFNα target genes. A LV-βGalactosidase reporter construct was delivered intravesically, and urinary IFNα levels were measured in mice treated with LV-IFNα or control virus to assess gene transfer. To assess survival benefit, the MB49 intravesical tumor model and p53+/- C57/B6 mouse model were employed. We also assessed the role of combination therapy with immune checkpoint blockade using PD1 antibody using our MB49 intravesical model. Results: Efficient LV-IFNα transduction of BLCA cells resulted in increased expression of IFNα and its target genes and reduced cell viability vs. controls (p<0.001). Mechanistically, TRAIL dependent cytotoxicity in the LV-IFNα cells was rescued by Caspase8 inhibition. Urinary IFNα levels were elevated in mice receiving LV-IFNα compared with control virus. Overall survival improved in the MB49 model and BBN model in treated mice. LV-IFN induced intratumoral CD8+ T cell infiltration, high expression of PD-L1, and inhibited angiogenesis in BBN model whereas in the MB49 tumor response was mediated by TRAIL. Combination therapy with PD1 resulted in further improved survival. Conclusions: LV-IFNα effectively upregulated IFNα target genes, was cytotoxic to murine BLCA cells, and improved the survival in mouse models. Combining it with PD1 therapy appears to further improve survival.

AAV-Mediated Gene Delivery to Foveal Cones.

Adeno-associated virus (AAV) has emerged as the vector of choice for delivering genes to the mammalian retina. From the first gene therapy to receive FDA approval for the inherited retinal disease (Luxturna™) to more recent clinical trials using microbial opsins to regain light sensitivity, therapeutic transgenes rely on AAV vectors for safe and efficient gene delivery to retinal cells. Such vectors are administered to the retina via subretinal (SR) injection or intravitreal (IVT) injection routes depending on the targeted retinal cell type. An attractive target for gene therapy is the fovea, bearing the highest concentration of cone cells responsible for our high acuity daylight vision. However, previous clinical trials and large animal studies reported that SR administration of vector under the cone-exclusive fovea disrupts its fine structure and might impair visual acuity. Due to its technical difficulty and potential risks, alternatives to vector injection under this delicate region have been investigated by using novel AAV capsid variants identified via rational design or directed evolution. We recently established new vector-promoter combinations to overcome the limitations associated with AAV-mediated cone transduction in the fovea. Our methods provide efficient foveal cone transduction without detaching this delicate region and rely on the use of engineered AAVs and optimal promoters compatible with optogenetic vision restoration. Here we describe in detail our AAV vectors, methods for intravitreal and subretinal injections as well as pre- and postoperative procedures as performed in cynomolgus macaques.

Coactivation of Endogenous Wnt10b and Foxc2 by CRISPR Activation Enhances BMSC Osteogenesis and Promotes Calvarial Bone Regeneration.

CRISPR activation (CRISPRa) is a burgeoning technology for programmable gene activation, but its potential for tissue regeneration has yet to be fully explored. Bone marrow-derived mesenchymal stem cells (BMSCs) can differentiate into osteogenic or adipogenic pathways, which are governed by the Wnt (Wingless-related integration site) signaling cascade. To promote BMSC differentiation toward osteogenesis and improve calvarial bone healing by BMSCs, we harnessed a highly efficient hybrid baculovirus vector for gene delivery and exploited a synergistic activation mediator (SAM)-based CRISPRa system to activate Wnt10b (that triggers the canonical Wnt pathway) and forkhead c2 (Foxc2) (that elicits the noncanonical Wnt pathway) in BMSCs. We constructed a Bac-CRISPRa vector to deliver the SAM-based CRISPRa system into rat BMSCs. We showed that Bac-CRISPRa enabled CRISPRa delivery and potently activated endogenous Wnt10b and Foxc2 expression in BMSCs for >14days. Activation of Wnt10b or Foxc2 alone was sufficient to promote osteogenesis and repress adipogenesis invitro. Furthermore, the robust and prolonged coactivation of both Wnt10b and Foxc2 additively enhanced osteogenic differentiation while inhibiting adipogenic differentiation of BMSCs. The CRISPRa-engineered BMSCs with activated Wnt10b and Foxc2 remarkably improved the calvarial bone healing after implantation into the critical-sized calvarial defects in rats. These data implicate the potentials of CRISPRa technology for bone tissue regeneration.

TAT-functionalized PEI-grafting rice bran polysaccharides for safe and efficient gene delivery

Polysaccharides are considered to be promising candidates for non-viral gene delivery because of their molecular diversity, which can be modified to fine-tune their physicochemical properties. In this work, transcriptional activator protein (TAT) functionalized PEI grafted polysaccharide polymer (PRBP) was prepared by using rice bran polysaccharide as the starting material, and characterized by various methods. The potential of TAT functionalized PRBP (PRBP-TAT) as gene vector was studied in vitro, including DNA loading capacity, DNA protection ability and biocompatibility. The cell uptake and transfection efficiency of the PRBP-TAT/pDNA polyplexes were studied. The results showed that PRBP-TAT could completely condense DNA at N/P 2. The PRBP-TAT/pDNA polyplexes could protect DNA from degrading by DNase and were efficiently internalized by cells. Biocompatibility result showed that PRBP-TAT had no significant cytotoxicity and effect on cell proliferation. At low N/P ratios of 1–3.5, PRBP-TAT showed higher transfection efficiency than PEI30k and PEI30k-grafted rice bran polysaccharide. PRBP-TAT and PEI showed the highest transfection efficiency of 42.8% and 28.1% when pDNA is 2 µg and N/P ratio is 1.5, respectively, while PRBP showed the highest transfection efficiency of 37.3% at N/P 2.5. These results indicate that PTA is a promising candidate vector for safe and efficient gene delivery.

Molecular characterization of novel Adeno-associated virus variants infecting human tissues

Despite the many advantages with Adeno-associated virus (AAV) based vectors for gene therapy, certain barriers related to host permissivity and immune response precludes their widespread application in humans. A comprehensive study of the distribution and complexity of naturally occurring AAV in human tissues should facilitate their optimal utilization for gene therapy and tissue targeting in humans. A total of 205 samples, comprising 198 tissue samples from individuals of Indian origin and 7 different cell lines were investigated. A panel of 8 primate samples was used as controls. DNA from these samples was screened for the AAV capsid specific signature regions by a modified PCR and DNA sequencing approach. Further, we generated a single point mutation (S224A) in AAV3 vector, analogous to the mutation identified in a novel AAV3 sequence variant isolated from a peripheral blood stem cell (PBSC) sample. We further studied the infectivity of these vectors in HeLa and HS5 cells in vitro. Of the 205 samples analyzed, an AAV specific signature DNA sequence was detected in 92 samples (45%), including 85 out of 198 human tissues and in all the 7 human cell lines investigated. DNA sequencing analysis showed that AAV6(34%) was the most common serotype and identified predominantly in PBSCs. Interestingly, a comparative genotypic analysis in primate samples identified AAV3 specific DNA in most of the bone marrow or liver tissue analyzed (n = 7/8) suggesting species-specific differences in AAV infectivity. Further characterization of an AAV3 serotype variant isolated from the PBSCs was non-infectious in vitro, possibly due to altered receptor affinity. Our data outlines the genetic diversity and the distribution of AAV serotypes infecting humans and provides a basis for their further characterization to generate efficient gene delivery vectors.

Development of a safe and efficient gene delivery system based on a biodegradable tannic acid backbone

Finding a safe and efficient gene delivery vector is a major international challenge facing the development of gene therapy. Tannic acid (TA) is a natural cross-linker owing to its hydroxyl and carboxyl groups that can interact with biopolymers for different biomaterial design. In this work, three polyethyleneimine-modified TA polymers were prepared, and the polymers were characterized by FTIR, UV–vis, elemental analysis and 1H NMR. The potential of PTAs as gene vector was studied in vitro, including DNA loading capacity, DNA protection ability and biocompatibility. In addition, the particle size, zeta potential, DNA encapsulation efficiency, cell uptake and transfection efficiency of the PTA-pDNA polyplexes were also studied. The results showed that PTA2k and PTA30k could completely condense DNA at N/P of 2, and PTA600 could only completely condense DNA at N/P of 50. The PTA/pDNA polyplexes could protect DNA from degrading by DNA enzymes and could be efficiently uptaked by cells. Biocompatibility assay showed that PTA had no significant cytotoxicity and effect on cell proliferation compared to PEI. At low N/P ratios of 1–4, PTA showed higher transfection efficiency than PEI, and the transfection efficiency increased with the increase of PEI molecular weight in PTA. At N/P of 3, PTA30k showed the highest transfection efficiency of 23.8%, while PEI30k showed only 6.7%. These results indicate that PTA is a promising candidate vector for safe and efficient gene delivery.

Polyethylenimine-associated cerium oxide nanoparticles: A novel promising gene delivery vector

AimsThe development of highly efficient and low toxic non-viral gene delivery vectors is the most challenging issues for successful application of gene therapy. A particular focus has been on understanding structure-activity relationships for transfection activity and toxicity of polyethylenimine (PEI). During the last decade, the use of cerium oxide nanoparticles (CeO2-NPs) in biomedicine has attracted much attention due to their pH-dependent antioxidant activity. CeO2-NPs provide protection normal cells from various forms of reactive oxygen species, but possess innate cytotoxicity and apoptosis to cancer cells. The purpose of this study was to design a new class of gene carriers by low molecular weight PEI (B-PEI 10 kDa) coordination onto CeO2-NPs. Main methodsB-PEI 10 kDa was conjugated to CeO2-NPs by Epichlorohydrin linker. Transfection efficiency, cytotoxic and apoptotic effects of pDNA-PEI-CeO2 NPs were evaluated on WEHI 164 cancer cells and normal L929 cells lines. Key findingsPEI-CeO2 NPs was able to condense the pDNA at carrier/plasmid (C/P) weight ratios of 0.5. The size and zeta potential of pDNA-PEI-CeO2 NPs were 124 ± 7 nm and 22 ± 2 mV, respectively. The transfection efficacy of synthesized pDNA-PEI-CeO2 NPs improved and the cytotoxicity was decreased compared to pDNA-PEI. Moreover, pDNA-PEI-CeO2 NPs induced more apoptosis than unmodified PEI and CeO2-NPs control groups. pDNA-PEI-CeO2 NPs displayed more transfection, cytotoxicity, and apoptosis in WEHI 164 cancer cells than normal L929 cells. SignificanceIn conclusion, PEI-CeO2 nanocarriers could act as a potential candidate for gene and drug delivery to cancerous and tumor cells.

Recent Advances in Chitosan-Based Carriers for Gene Delivery

Approximately 4000 diseases are associated with malfunctioning genes in a particular cell type. Gene-based therapy provides a platform to modify the disease-causing genes expression at the cellular level to treat pathological conditions. However, gene delivery is challenging as these therapeutic genes need to overcome several physiological and intracellular barriers in order, to reach the target cells. Over the years, efforts have been dedicated to develop efficient gene delivery vectors to overcome these systemic barriers. Chitosan, a versatile polysaccharide, is an attractive non-viral vector material for gene delivery mainly due to its cationic nature, biodegradability and biocompatibility. The present review discusses the design factors that are critical for efficient gene delivery/transfection and highlights the recent progress of gene therapy using chitosan-based carriers.

Encapsulation of Plasmid DNA by Nanoscale Metal-Organic Frameworks for Efficient Gene Transportation and Expression.

The intracellular delivery and functionalization of genetic molecules play critical roles in gene-based theranostics. In particular, the delivery of plasmid DNA (pDNA) with safe nonviral vectors for efficient intracellular gene expression has received increasing attention; however, it still has some limitations. A facile one-pot method is employed to encapsulate pDNA into zeolitic imidazole framework-8 (ZIF-8) and ZIF-8-polymer vectors via biomimetic mineralization and coprecipitation. The pDNA molecules are found to be well distributed inside both nanostructures and benefit from their protection against enzymatic degradation. Moreover, through the use of a polyethyleneimine (PEI) 25 kD capping agent, the nanostructures exhibit enhanced loading capacity, better pH responsive release, and stronger binding affinity to pDNA. From in vitro experiments, the cellular uptake and endosomal escape of the protected pDNA are greatly improved with the superior ZIF-8-PEI 25 kD vector, leading to successful gene expression with high transfection efficacy, comparable to expensive commercial agents. New cost-effective avenues to develop metal-organic-framework-based nonviral vectors for efficient gene delivery and expression are provided.

Self‐Assembled and Size‐Controllable Oligonucleotide Nanospheres for Effective Antisense Gene Delivery through an Endocytosis‐Independent Pathway

AbstractThe development of efficient gene delivery vectors has faced two major challenges, namely endo‐ and lysosomal escape and intracellular release. To address these problems, we developed an oligonucleotide (ON)‐template‐assisted polymerization approach to create ON nanospheres as gene vectors. Guanidinium‐containing disulfide monomers were organized on the ON templates to increase their effective local concentrations. Consequently, ring‐opening disulfide‐exchange polymerization between monomers was accelerated, further facilitating the self‐assembly of ON nanospheres. The size of these nanospheres was controlled by varying the length of the ON templates. Importantly, the nanospheres can be directly delivered into the cytosol through an endocytosis‐independent pathway, which is followed by intracellular depolymerization in the reductive cytosolic environment to release the packaged ONs, resulting in efficient gene silencing. The ON nanospheres thus hold great promise as candidates for gene therapy.

Self-Assembled and Size-Controllable Oligonucleotide Nanospheres for Effective Antisense Gene Delivery through an Endocytosis-Independent Pathway.

The development of efficient gene delivery vectors has faced two major challenges, namely endo- and lysosomal escape and intracellular release. To address these problems, we developed an oligonucleotide (ON)-template-assisted polymerization approach to create ON nanospheres as gene vectors. Guanidinium-containing disulfide monomers were organized on the ON templates to increase their effective local concentrations. Consequently, ring-opening disulfide-exchange polymerization between monomers was accelerated, further facilitating the self-assembly of ON nanospheres. The size of these nanospheres was controlled by varying the length of the ON templates. Importantly, the nanospheres can be directly delivered into the cytosol through an endocytosis-independent pathway, which is followed by intracellular depolymerization in the reductive cytosolic environment to release the packaged ONs, resulting in efficient gene silencing. The ON nanospheres thus hold great promise as candidates for gene therapy.

Lentiviral interferon: A novel method for gene therapy in bladder cancer.

456 Background: Gene therapy for bladder cancer (BLCA) is rapidly evolving. We reported that intravesical adenoviral interferon-alpha (Ad-IFNα) produced a complete response in 35% of patients with BCG-unresponsive BLCA enrolled in a Phase II trial. Lentivirus (LV) is another potential vector for intravesical delivery of IFNα. Unlike the adenovirus, LV can infect non-dividing cells and integrate into the host’s genome, making it one of the most efficient gene delivery vectors. The objective of this study was to investigate lentiviral interferon-alpha (LV-IFNα) BLCA gene therapy in preclinical models. Methods: Murine BLCA cell lines were transduced in-vitro with LV-IFNα using a multiplicity of infection (MOI) of 2:1. IFNα levels were measured by ELISA. Cell viability was assessed using Trypan blue dye exclusion. qPCR was used to identify expression of IFNα target genes. A LV-βGalactosidase reporter construct was delivered intravesically, and urinary IFNα levels were measured in mice treated with LV-IFNα or control virus to assess gene transfer. To assess survival benefit, p53+/- C57/B6 mice were exposed to N-butyl-N-(4-hydroxybutyl)-nitrosamine (BBN) to induce CIS and then treated with LV-IFNα or control virus, and sacrificed when moribund. Results: Efficient LV-IFNα transduction of BLCA cells was observed at an MOI of 2:1, resulting in increased expression of IFNα and its target genes PDL-1, TRAIL, and IRF7 (p<0.001), and reduced cell viability vs. controls (p<0.001). Mechanistically, TRAIL dependent cytotoxicity in the LV-IFNα cells was rescued by Caspase 8 inhibition. βGal expression confirmed efficient transduction of murine urothelium. Urinary IFNα levels were elevated in mice receiving LV-IFNα compared with control virus. BBN mice treated with LV-IFNα had longer overall survival than mice treated with control virus (p=0.04). LV-IFNα induced intratumoral CD8+ T cell infiltration, high expression of PD-L1, and inhibited angiogenesis. Conclusions: LV-IFNα effectively upregulated IFNα target genes, was cytotoxic to murine BLCA cells, and improved the survival of BBN tumor-bearing mice. LV appears to be a promising vector for intravesical gene delivery.

Peptide-grafted dextran vectors for efficient and high-loading gene delivery.

Among various polymeric gene delivery systems, peptide-based vectors demonstrate great potential owing to their unique structure and properties, including flexibility; however, there is insufficient molecular understanding of the role and properties of amino acids as building blocks in gene delivery. In this work, we constructed a series of histidine (H)-containing peptide-grafted dextran (D-RxHy) vectors via a simple two-step reaction of dextran with five RxHyC peptides: R7H3C, R5H3C, R5H5C, R3H5C, and R3H7C. The gel electrophoresis study unveiled the DNA-binding ability of H residues. While all D-RxHy vectors possess similarly low cytotoxicity, D-R3H7 exhibited the highest gene transfection efficiency. Interestingly, at the low nitrogen to phosphate (N/P) ratio of 2, D-R3H7 displayed a 6-8-fold higher luciferase expression compared to the gold standard branched PEI (25k). D-R3H7 and D-R5H5 demonstrated favorable cell uptake rates. A chloroquine-treated transfection assay confirmed the key effect of the high buffering capacity of H-rich D-R3H7 on its high gene transfection efficiency, especially at low N/P ratios. The present work unveiled that histidine is critical for both DNA condensation and the accurate control of endosomal escape. The tunable D-RxHy platform not only demonstrates promising potential for therapeutic purposes but can also be used as a tool to elucidate the molecular mechanism of polymer-based transfection.

Baculovirus as an efficient vector for gene delivery into mosquitoes

Efficient gene delivery technologies play an essential role in the gene functional analyses that are necessary for basic and applied researches. Mosquitoes are ubiquitous insects, responsible for transmitting many deadly arboviruses causing millions of human deaths every year. The lack of efficient and flexible gene delivery strategies in mosquitoes are among the major hurdles for the study of mosquito biology and mosquito-pathogen interactions. We found that Autographa californica multiple nucleopolyhedrovirus (AcMNPV), the type baculovirus species, can efficiently transduce mosquito cells without viral propagation, allowing high level gene expression upon inducement by suitable promoters without obvious negative effects on cell propagation and viability. AcMNPV transduces into several mosquito cell types, efficiently than in commonly used mammalian cell lines and classical plasmid DNA transfection approaches. We demonstrated the application of this system by expressing influenza virus neuraminidase (NA) into mosquito hosts. Moreover, AcMNPV can transduce both larvae and adults of essentially all blood-sucking mosquito genera, resulting in bright fluorescence in insect bodies with little or no tissue barriers. Our experiments establish baculovirus as a convenient and powerful gene delivery vector in vitro and in vivo that will greatly benefit research into mosquito gene regulation, development and the study of mosquito-borne viruses.

Structure‐Optimized Interpolymer Polyphosphazene Complexes for Effective Gene Delivery against Glioblastoma

AbstractSafe and efficient gene delivery vectors will enhance the prospects for polynucleotide‐based therapies. Herein a new approach toward structurally optimized gene vector design based on the preparation of clickable poly(allylamino‐phosphazene)s that can be converted to several cationic and anionic derivatives via thiol–ene addition is described. Simultaneous co‐incubation of alkylamine‐ and alkylcarboxylate‐poly(phosphazenes) with polynucleotide generates binary polyelectrolyte nanoparticles. Screening of a series of these complexes for transfection in glioblastoma cells shows that the inclusion of 6‐mercaptohexanoic acid substituted poly(phosphazene)s in the complexes results in six‐fold and 19‐fold higher luciferase expression in U87MG cells and GBM1 primary cells, respectively. This effect is attributed to the specific ionization properties of these materials that improved polyplex intracellular trafficking. Transfection in 3D‐spheroid models and subcutaneous xenograft U87MG tumors confirms higher transgene expression for the binary cationic/anionic poly(phosphazene) complexes compared to the related polycation‐pDNA complexes and to PEI‐pDNA complexes. The data also indicate a notable capacity of the mixed complexes to deliver genes to the inner cores of tumor spheroids. Extension of this approach to siRNA delivery shows that the mixed poly(phosphazene) complexes can silence DYRK1A, a gene implicated in glioblastoma initiation and progression, reducing U87MG cell renewal in vitro and delaying tumor growth in vivo.

Laser-assisted Lentiviral Gene Delivery to Mouse Fertilized Eggs.

Lentiviruses are efficient vectors for gene delivery to mammalian cells. Following transduction, the lentiviral genome is stably incorporated into the host chromosome and is passed on to progeny. Thus, they are ideal vectors for creation of stable cell lines, in vivo delivery of indicators, and transduction of single cell fertilized eggs to create transgenic animals. However, mouse fertilized eggs and early stage embryos are protected by the zona pellucida, a glycoprotein matrix that forms a barrier against lentiviral gene delivery. Lentiviruses are too large to penetrate the zona and are typically delivered by microinjection of viral particles into the perivitelline cavity, the space between the zona and the embryonic cells. The requirement for highly skilled technologists and specialized equipment has minimized the use of lentiviruses for gene delivery to mouse embryos. This article describes a protocol for permeabilizing the mouse fertilized eggs by perforating the zona with a laser. Laser-perforation does not result in any damage to embryos and allows lentiviruses to gain access to embryonic cells for gene delivery. Transduced embryos can develop into blastocyst in vitro, and if implanted in pseudopregnant mice, develop into transgenic pups. The laser used in this protocol is effective and easy to use. Genes delivered by lentiviruses stably incorporate into mouse embryonic cells and are germline transmittable. This is an alternative method for creation of transgenic mice that requires no micromanipulation and microinjection of fertilized eggs.

Gonadotropin-releasing hormone-modified chitosan as a safe and efficient gene delivery vector for spermatogonia cells.

The use of male gonadal tissue as a site for the local delivery of DNA is an interesting concept. Previously, we reported synthesis, physiochemical and biological properties of gonadotropin-releasing hormone (GnRH)-conjugated chitosan as a carrier for DNA delivery to GnRH receptor-overexpressing cells. In this study, the application of modified chitosan as a potential vector for gene delivery to testicular cells was carried out. Transfection efficiency was investigated in mouse-derived spermatogonia cells (GC-1 cells) using green fluorescent protein as a reporter gene. GnRH-conjugated chitosan exhibited higher transfection activity and specificity compared to the unmodified chitosan. Furthermore, the GnRH-modified chitosan showed less cytotoxicity. In conclusion, we have developed and successfully tested the GnRH-modified chitosan for delivery of a transgene of interest to spermatogonia cells in vitro. Such vector could be useful in particular for testis-mediated gene transfer.

Hybrid capsules as efficient non-viral vector for gene delivery into cells

Advances in the field of nanotechnology make it possible to employ nano- and microparticles as delivery carriers of genetic materials. In this study, hollow capsules of different composition were used as non-viral vectors to deliver plasmids into human cervical carcinoma cells (HeLa). Plasmids were encoded to express green fluorescent protein (eGFP) inside cells. Hybrid capsules were produced from degradable polyelectrolytes with an outer silica layer. Capsules were characterized with scanning electron and bright field microscopy. Successful cell transfection was verified with the confocal laser scanning microscope (CLSM).