Improved Gene Delivery Research Articles

Lipid-based Non-viral Vector: Promising Approach for Gene Delivery.

The present review aims to discuss various strategies to overcome intracellular and extracellular barriers involved in gene delivery as well as the advantages, challenges, and mechanisms of gene delivery using non-viral vectors. Additionally, patents, clinical studies, and various formulation approaches related to lipid-based carrier systems are discussed. Data were searched and collected from Google Scholar, ScienceDirect, Pubmed, and Springer. In this review, we have investigated the advantages of non-viral vectors over viral vectors. The advantage of using non-viral vectors are that they seek more attention in different fields. They play an important role in delivering the genetic materials. However, few nonviral vector-based carrier systems have been found in clinical settings. Challenges are developing more stable, site-specific gene delivery and conducting thorough safety assessments to minimize the undesired effects. In comparison to viral vectors, nonviral vector-based lipid nanocarriers have more advantages for gene delivery. Gene therapy research shows promise in addressing health concerns. Lipid-based nanocarriers can overcome intracellular and extracellular barriers, allowing efficient delivery of genetic materials. Non-viral vectors are more attractive due to their biocompatibility, ease of synthesis, and cost-effectiveness. They can deliver various nucleic acids and have improved gene delivery efficacy by avoiding degradation steps. Despite limited clinical use, many patents have been filed for mRNA vaccine delivery using non-viral vectors.

DOTAP Modified Formulations of Aminoacid Based Cationic Liposomes for Improved Gene Delivery and Cell Viability.

The liposomal systems proved remarkably useful for the delivery of genetic materials but enhancing their efficacy remains a significant challenge. While structural alterations could result in the discovery of more effective transfecting lipids, improving the efficacy of widely used lipid carriers is also crucial in order to compete with viral vectors for gene delivery. Herein, we developed formulations of commercially available lipid, 1,2-dioleoyl-3-trimethylammonium-propane (DOTAP) with synthetic cationic lipids containingamino acids, cystine (CTT) or arginine (AT) in the head group. These lipids were used to formulatewith different co-lipid compositions and werebroadly categorised into two types: amino acid-based liposomes without DOTAP (CTTD and ATD) and those with DOTAP (DtATD and DtCTTD). Optimized lipid-DNA complexes of DOTAP-incorporated formulations (DtATD and DtCTTD) exhibited enhanced efficacy in transfection compared to formulations lacking DOTAP as well as commercial formulations such as DOTAP:DOPE. Notably, DtCTTD displayed superior transfection capabilities in prostate cancer (PC3) and lung cancer (A549) cell lines when compared to the widely used commercial transfection reagent, Lipofectamine. Collectively, the findings from this study suggest that DOTAP-incorporated formulations derived from amino acid-based liposomes, hold promise as effective tools for improving transfection efficacy with reduced toxicity, offering potential advancements in gene delivery applications.

Optimization of an adeno-associated viral vector for epidermal keratinocytes in vitro and in vivo

BackgroundLocal gene therapies, including in vivo genome editing, are highly anticipated for the treatment of genetic diseases in skin, especially the epidermis. While the adeno-associated virus (AAV) is a potent vector for in vivo gene delivery, the lack of efficient gene delivery methods has limited its clinical applications. ObjectiveTo optimize the AAV gene delivery system with higher gene delivery efficiency and specificity for epidermis and keratinocytes (KCs), using AAV capsid and promoter engineering technologies. MethodsAAV variants with mutations in residues reported to be critical to determine the tropism of AAV2 for KCs were generated by site-directed mutagenesis of AAVDJ. The infection efficiency and specificity for KCs of these variants were compared with those of previously reported AAVs considered to be suitable for gene delivery to KCs in vitro and in vivo. Additionally, we generated an epidermis-specific promoter using the most recent short-core promoter and compared its specificity with existing promoters. ResultsA novel AAVDJ variant capsid termed AAVDJK2 was superior to the existing AAVs in terms of gene transduction efficiency and specificity for epidermis and KCs in vitro and in vivo. A novel tissue-specific promoter, termed the K14 SCP3 promoter, was superior to the existing promoters in terms of gene transduction efficiency and specificity for KCs. ConclusionThe combination of the AAVDJK2 capsid and K14 SCP3 promoter improves gene delivery to epidermis in vivo and KCs in vitro. The novel AAV system may benefit experimental research and development of new epidermis-targeted gene therapies.

Synthesis and Evaluation of Ph and Temperature Stimuli-Responsive Magnetic Nanohydrogels for Gene Delivery

The offer of gene delivery technologies as a promising approach to treating diverse diseases has revolutionized human medicine during the last two decades. So, the application of suitable vectors, particularly polymers with substrates with unique physicochemical properties for the transfer of targeted genes to logical sites for effective treatment, plays an indispensable role for more personalized medicine and improves the safety profile in response to continuing to use new medical technologies. For this purpose, we synthesized nanocarriers with a two-block cationic hydrogel, magnetic and non-magnetic, based on N-isopropyl acrylamide (NIPAM) and quaternary alkyl ammonium halide salts of DMAEMA (DMAEMAQ) with pH and temperature responsiveness via the free radical polymerization technique. The bulk properties of these co-polymers were characterized by using Fourier transform infrared spectroscopy, 1H NMR spectroscopy, Zeta potential, lower critical solution temperature (LCST), and gel electrophoresis to show the loading of nanoparticles with the gene. In the results, magnetic P[NIPAM-DMAEMAQ] hydrogel showed controllable responsive properties determined by the nature of the cationic charge +24.7 mV incorporated, nanosize around 86.95 and 91.22 nm, and efficiency loaded with the gene more than 95%. As well, the synthesized nanohydrogel exhibited a sharp volume-phase transition in water at a LCST of ∼40 °C. So, the combination of both monomers yielded an interesting system with high transfection efficiency and compliant biocompatibility characteristics, which could effectively achieve gene loading. Also, the magnetic potential of nanohydrogel was determined as a vector to deliver genes to localized sites. Notably, the synthesized combination P[NIPAM-DMAEMAQ] nanohydrogel has been considered a transfection of the biodegradable and biocompatible magnetic nanoparticle sensitive to tunable pH and temperature responsiveness, demonstrating that it will hold a promising approach as a potential carrier to improve gene delivery therapeutic efficacy in cancer and different disease treatments.

Adenovirus expressing nc886, an anti-interferon and anti-apoptotic non-coding RNA, is an improved gene delivery vector

Recombinant adenovirus (rAdV) vector is the most promising vehicle to deliver an exogenous gene into target cells and is preferred for gene therapy. Exogenous gene expression from rAdV is often too inefficient to induce phenotypic changes and the amount of administered rAdV must be very high to achieve a therapeutic dose. However, it is often hampered because a high dose of rAdV is likely to induce cytotoxicity by activating immune responses. nc886, a 102-nucleotide non-coding RNA that is transcribed by RNA polymerase III, acts as an immune suppressor and a facilitator of AdV entry into the nucleus. Therefore, in this study, we have constructed an rAdV expressing nc886 (AdV:nc886), to explore whether AdV:nc886 overcomes the aforementioned drawbacks of conventional rAdV vectors. When infected into mouse cell lines and mice, AdV:nc886 expresses a sufficient amount of nc886, which suppresses the induction of interferon-stimulated genes and apoptotic pathways triggered by AdV infection. As a result, AdV:nc886 is less cytotoxic and produces more rAdV-delivered gene products, compared with the parental rAdV vector lacking nc886. In conclusion, this study demonstrates that the nc886-expressing rAdV could become a superior gene delivery vehicle with greater safety and higher efficiency for in vivo gene therapy.

Broadening the Scope of Sapofection: Cationic Peptide-Saponin Conjugates Improve Gene Delivery In Vitro and In Vivo.

Gene therapies represent promising new therapeutic options for a variety of indications. However, despite several approved drugs, its potential remains untapped. For polymeric gene delivery, endosomal escape represents a bottleneck. SO1861, a naturally occurring triterpene saponin with endosomal escape properties isolated from Saponaria officinalis L., has been described as additive agent to enhance transfection efficiency (sapofection). However, the challenge to synchronize the saponin and gene delivery system in vivo imposes limitations. Herein, we address this issue by conjugating SO1861 to a peptide-based gene vector using a pH-sensitive hydrazone linker programmed to release SO1861 at the acidic pH of the endosome. Nanoplexes formulated with SO1861-equipped peptides were investigated for transfection efficiency and tolerability in vitro and in vivo. In all investigated cell lines, SO1861-conjugated nanoplexes have shown superior transfection efficiency and cell viability over supplementation of transfection medium with free SO1861. Targeted SO1861-equipped nanoplexes incorporating a targeting peptide were tested in vitro and in vivo in an aggressively growing neuroblastoma allograft model in mice. Using a suicide gene vector encoding the cytotoxic protein saporin, a slowed tumor growth and improved survival rate were observed for targeted SO1861-equipped nanoplexes compared to vehicle control.

Beyond Lipids: Exploring Advances in Polymeric Gene Delivery in the Lipid Nanoparticles Era.

The recent success of gene therapy during the COVID-19 pandemic has underscored the importance of effective and safe delivery systems. Complementing lipid-based delivery systems, polymers present a promising alternative for gene delivery. Significant advances have been made in the recent past, with multiple clinical trials progressing beyond phase I and several companies actively working on polymeric delivery systems which provides assurance that polymeric carriers can soon achieve clinical translation. The massive advantage of structural tunability and vast chemical space of polymers is being actively leveraged to mitigate shortcomings of traditional polycationic polymers and improve the translatability of delivery systems. Tailored polymeric approaches for diverse nucleic acids and for specific subcellular targets are now being designed to improve therapeutic efficacy. This review describes the recent advances in polymer design for improved gene delivery by polyplexes and covalent polymer-nucleic acid conjugates. The review also offers a brief note on novel computational techniques for improved polymer design. The review concludes with an overview of the current state of polymeric gene therapies in the clinic as well as future directions on their translation to the clinic.

Abstract 7257: Examining the promise of precision medicine in immuno-oncology: Vectors for targeted therapeutic delivery

Abstract At the forefront of therapeutic delivery is an array of vectors and targeting methods that hold immense promise for precision medicine. Vehicles such as viral vectors (AAV and lentivirus), lipid nanoparticles (LNPs) or liposomes, and peptide micelles each possess distinct and inherent properties, empowering researchers with tools to navigate the intricate challenges of specificity and efficiency in drug transport. Herein, we discuss and demonstrate design principles underpinning these vectors, elucidating their unique mechanisms for targeted delivery including:- A high-throughput viral packaging process to enable rapid downstream CRISPR or shRNA screening- Proprietary AAV plasmid synthesis and preparation techniques to maintain ITR integrity and improve gene delivery- Rapid synthesis, in vitro transcription, and novel sequencing of mRNA constructs for complete characterization of critical components such as the polyA tailBy synthesizing advancements in vector technologies, this poster serves as a roadmap for researchers and practitioners navigating the evolving landscape of targeted drug delivery in immuno-oncology. Citation Format: Crystal Richardson, Prassanna Rao, Cassandra Koole, Michael J. Karney, Sumit Kumar. Examining the promise of precision medicine in immuno-oncology: Vectors for targeted therapeutic delivery [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2024; Part 1 (Regular Abstracts); 2024 Apr 5-10; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2024;84(6_Suppl):Abstract nr 7257.

Effect of ursodiol on alginate/PLL nanoparticles with non-ionic surfactant for gene delivery

Hearing loss is a widespread condition, affecting people from a range of demographics. Gene therapy is an emerging method for the amelioration of this condition. Challenges associated with the delivery of genes to various sites within the ear remain a significant challenge. In the present work, a novel polymer nanoparticle delivery system was developed, incorporating a bile acid excipient. Bile acids have previously been shown to improve drug delivery through their permeation enhancing properties; however, few studies report their use in gene delivery systems. Nanoparticles were developed with sodium alginate and poly-L-lysine through an ionotropic gelation method. Various surfactants including Tween-80 and poly-ethylene glycol 6000 were incorporated to both improve the solubility of the bile acid, ursodiol, and to modify nanoparticle properties. The evaluation of the nanoparticle’s safety profiles was the primary outcome of this study. The secondary aims were to perform genetic studies, such as transfection efficiency. The nanoparticles generated in this study demonstrated formulation-dependent variability in particle size ranging from 30 to 300 nm. Several of the developed formulations demonstrated suitable safety profiles; further, the introduction of bile acid helped to reduce toxicity. Transfection efficiency for all formulations remained low, potentially due to poor plasmid release inside the cell. Poor transfection efficiency is one of the key pitfalls associated with polymer nanoparticles Overall the present study developed nanoparticles with suitable safety profiles but limited efficacy. The use of modified polymers, additional excipients, and cell-targeting peptides are potential methods that may be explored in future studies to help further improve gene delivery.

Improving Gene Delivery: Synergy between Alkyl Chain Length and Lipoic Acid for PDMAEMA Hydrophobic Copolymers.

In the field of gene delivery, hydrophobic cationic copolymers hold great promise. They exhibit improved performance by effectively protecting genetic material from serum interactions while facilitating interactions with cellular membranes. However, managing cytotoxicity remains a significant challenge, prompting an investigation into suitable hydrophobic components. A particularly encouraging approach involves integrating nutrient components, like lipoic acid, which is known for its antioxidant properties and diverse cellular benefits such as cellular metabolism and growth. In this study, a copolymer library comprising 2-(dimethylamino)ethyl methacrylate (DMAEMA) and lipoic acid methacrylate (LAMA), combined with either n-butyl methacrylate (nBMA), ethyl methacrylate (EMA), or methyl methacrylate (MMA), is synthesized. This enables to probe the impact of lipoic acid incorporation while simultaneously exploring the influence of pendant acyclic alkyl chain length. The inclusion of lipoic acid results in a notable boost in transfection efficiency while maintaining low cytotoxicity. Interestingly, higher levels of transfection efficiency are achieved in the presence of nBMA, EMA, or MMA. However, a positive correlation between pendant acyclic alkyl chain length and cytotoxicity is observed. Consequently, P(DMAEMA-co-LAMA-co-MMA), emerges as a promising candidate. This is attributed to the optimal combination of low cytotoxic MMA and transfection-boosting LAMA, highlighting the crucial synergy between LAMA and MMA.

Development of a stable Sf9 insect cell line to produce VSV-G pseudotyped baculoviruses.

Baculoviruses have shown great potential as gene delivery vectors in mammals, although their effectiveness in transferring genes varies across different cell lines. A widely employed strategy to improve transduction efficiency is the pseudotyping of viral vectors. In this study, we aimed to develop a stable Sf9 insect cell line that inducibly expresses the G-protein of the vesicular stomatitis virus to pseudotype budded baculoviruses. It was obtained by inserting the VSV-G gene under the control of the very strong and infection-inducible pXXL promoter and was subsequently diluted to establish oligoclonal lines, which were selected by the fusogenic properties of VSV-G and its expression levels in infected cells and purified budded virions. Next, to enhance the performance of the cell line, the infection conditions under which functional pseudotyped baculoviruses are obtained were optimized. Finally, different baculoviruses were pseudotyped and the expression of the transgene was quantified in mammalian cells of diverse origins using flow cytometry. The transduction efficiency of pseudotyped baculovirus consistently increased across all tested mammalian cell lines compared with control viruses. These findings demonstrate the feasibility and advantages of improving gene delivery performance without the need to insert the pseudotyping gene into the baculoviral genomes.

ZIF-8 Nanoparticle: A Valuable Tool for Improving Gene Delivery in Sperm-Mediated Gene Transfer

Metal–organic frameworks (MOFs) are porous materials with unique characteristics that make them well-suited for drug delivery and gene therapy applications. Among the MOFs, zeolitic imidazolate framework-8 (ZIF-8) has emerged as a promising candidate for delivering exogenous DNA into cells. However, the potential of ZIF-8 as a vector for sperm-mediated gene transfer (SMGT) has not yet been thoroughly explored.This investigation aimed to explore the potential of ZIF-8 as a vector for enhancing genetic transfer and transgenesis rates by delivering exogenous DNA into sperm cells. To test this hypothesis, we employed ZIF-8 to deliver a plasmid expressing green fluorescent protein (GFP) into mouse sperm cells and evaluated the efficiency of DNA uptake. Our findings demonstrate that ZIF-8 can efficiently load and deliver exogenous DNA into mouse sperm cells, increasing GFP expression in vitro. These results suggest that ZIF-8 is a valuable tool for enhancing genetic transfer in SMGT, with important implications for developing genetically modified animals for research and commercial purposes. Additionally, our study highlights the potential of ZIF-8 as a novel class of vectors for gene delivery in reproductive biology.Overall, our study provides a foundation for further research into using ZIF-8 and other MOFs as gene delivery systems in reproductive biology and underscores the potential of these materials as promising vectors for gene therapy and drug delivery.

Influence of the degree of arginine substitution on chitosan-N-arginine-based chitosomes: Insights for improved gene delivery systems

The exploration of lipid-biopolymer hybrid systems has opened new avenues for enhancing nucleic acid delivery in gene therapy. Chitosan-N-arginine (CSA), due to its increased hydrophilicity and intracellular penetration resulting from arginine conjugation, holds promise in such formulations. Despite significant advances in developing novel hybrid systems, the influence of the degree of substitution (DS) in CSA on lipid-CSA hybrid systems (chitosomes) and their complexation with pDNA remains unclear. This study aimed to fill this knowledge gap by examining how the DS in CSA influences chitosome formation and function. We synthesized two CSA variants with different DSs and subsequently produced chitosomes to assess their physicochemical properties and transfection potential. The ligation of arginine to chitosan in CSA preparations was confirmed by FTIR and H1-NMR spectroscopy, whereas elemental analysis indicated the DS at 5.7 % (CSA-6) and 3.4 % (CSA-3). Long-term stability was assessed in aqueous dispersions under storage temperatures of 25 °C or 4 °C, and we observed that CSA-3 and CSA-6 maintained their integrity for 11 and 12 months, respectively. Both chitosomes were successfully complexed with pDNA with the assistance of electrostatic interactions. Thermodynamic parameters indicated an exothermic interaction and a major contribution from the entropy change. Moreover, the chitosomes could protect pDNA from nucleases for 24 h, and the transfection efficiency in HeLa cells reached 21 %. Our findings suggest that while the DS in CSA influences pDNA complexation and compaction, it is not a determinant of the transfection efficiency. These findings will help in the design of improved hybrid nanosystems based on lipids and chitosan derivatives for nucleic acid delivery.

Stimulus-Responsive Nanodelivery and Release Systems for Cancer Gene Therapy: Efficacy Improvement Strategies.

Introduction of exogenous genes into target cells to overcome various tumor diseases caused by genetic defects or abnormalities and gene therapy, a new treatment method, provides a promising strategy for tumor treatment. Over the past decade, gene therapy has made exciting progress; however, it still faces the challenge of low nucleic acid delivery and release efficiencies. The emergence of nonviral vectors, primarily nanodelivery and release systems (NDRS), has resulted in a historic breakthrough in the application of gene therapy. NDRS, especially stimulus-responsive NDRS that can respond in a timely manner to changes in the internal and external microenvironment (eg, low pH, high concentration of glutathione/reactive oxygen species, overexpressed enzymes, temperature, light, ultrasound, and magnetic field), has shown excellent loading and release advantages in the precision and efficiency of tumor gene therapy and has been widely applied. The only disadvantage is that poor transfection efficiency limits the in-depth application of gene therapy in clinical practice, owing to the presence of biological barriers in the body. Therefore, this review first introduces the development history of gene therapy, the current obstacles faced by gene delivery, strategies to overcome these obstacles, and conventional vectors, and then focuses on the latest research progress in various stimulus-responsive NDRS for improving gene delivery efficiency. Finally, the future challenges and prospects that stimulus-responsive NDRS may face in clinical application and transformation are discussed to provide references for enhancing in-depth research on tumor gene therapy.

Comprehensive review on fluorescent carbon dots and their applications in nucleic acid detection, nucleolus targeted imaging and gene delivery.

Carbon dots (CDs), including carbon quantum dots, graphene quantum dots, carbon nanodots, and polymer dots, have gained significant attention due to their unique structural and fluorescence characteristics. This review provides a comprehensive overview of the classification, structural characteristics, and fluorescence properties of CDs, followed by an exploration of various fluorescence sensing mechanisms and their applications in gene detection, nucleolus imaging, and gene delivery. Furthermore, the functionalization of CDs with diverse surface ligand molecules, including dye molecules, nucleic acid probes, and metal derivatives, for sensitive nucleic acid detection is systematically examined. Fluorescence imaging of the cell nucleolus plays a vital role in examining intracellular processes and the dynamics of subcellular structures. By analyzing the mechanism of fluorescence and structure-function relationships inherent in CDs, the nucleolus targeting abilities of CDs in various cell lines have been discussed. Additionally, challenges such as the insufficient organelle specificity of CDs and the inconsistent mechanisms underlying nucleolus targeting have also been highlighted. The unique physical and chemical properties of CDs, particularly their strong affinity toward deoxyribonucleic acid (DNA), have spurred interest in gene delivery applications. The use of nuclear-targeting peptides, polymers, and ligands in conjunction with CDs for improved gene delivery applications have been systematically reviewed. Through a comprehensive analysis, the review aims to contribute to a deeper understanding of the potential and challenges associated with CDs in biomedical applications.

Research on the gene therapy and prevention of lung cancer

In recent years, there have been significant advancements in molecular biology, gene therapy technology, and high-tech testing techniques. As our understanding of the pathogenesis of lung cancer continues to deepen, it has become evident that gene therapy plays a crucial role in its treatment. This article provides an overview of tumor cell development, various gene therapy techniques including suicide gene therapy, silent gene therapy, cancer suppressor genetic therapy, and antibody genetic therapy. Additionally, it analyzes the application value, treatment technology, and safety concerns associated with gene therapy. The discussion also covers the safety issues and current application status of viral and nonviral vectors in gene therapy, comparing the advantages and disadvantages of different vector types. Furthermore, the article summarizes the future directions for designing and improving gene delivery vectors, along with their clinical application prospects. Ultimately, this article offers insights into the significance and treatment approaches for early prevention of lung cancer.

Peptide-modified PAMAM-based bone-targeting RNA delivery system

BackgroundOsteoporosis, among other bone diseases, has become a prevalent cause of decreased quality of life in older and postmenopausal women. Traditional anti-osteoporotic therapies, though widely prescribed, are limited by a lack of cell- or tissue-specific targeting ability and effectiveness without side effects. Gene therapy is rapidly replacing traditional therapeutics, primarily because of its specific targeting ability and efficiency. Among viral- and non-viral-based gene therapies, the latter is often preferred over the former due to lower cytotoxicity, immunogenicity, and ease of modification with different molecules to improve efficiency and extend gene expression. We designed and synthesized a multifunctional bone-targeting ribonucleic acid (RNA) delivery system based on polyamidoamine (PAMAM). PAMAM was modified with the serine-aspartate-serine-serine-aspartate (SDSSD) peptide to deliver antagomir 138-5p to osteoblasts (MC3T3-E1 cell line) in vitro and in vivo using the ovariectomized (OVX) mouse model.ResultsThe results showed that this system was less cytotoxic than polyethylenimine (PEI) and could bind to RNA favorably while maintaining gene delivery ability in vitro. In vivo data showed that the distal tibia and femur of the mice in the PAMAM-SDSSD (PS) + RNA group had improved bone mineral density (BMD), bone mineral content (BMC), and bone volume compared to those in the PS + Negative Control (NC) or OVX groups. Moreover, the femurs of the PS + RNA group mice demonstrated a higher breaking point, stress, stiffness, and elasticity than those of the PS + NC or OVX mice, suggesting improved femur strength in the OVX mice treated with RNA delivered through SDSSD-modified PAMAM.ConclusionThis study shows that SDSSD modification of PAMAM not only improves gene delivery capacity but also enhances the cell targeting efficiency of nanoparticles towards osteoblasts. The successful delivery of antagomir 138-5p to osteoblasts demonstrates cell-specificity and gene delivery to alleviate osteoporotic symptoms.

CAR Gene Delivery by T-cell Targeted Lentiviral Vectors is Enhanced by Rapamycin Induced Reduction of Antiviral Mechanisms.

Lentiviral vectors (LV) have become the dominant tool for stable gene transfer into lymphocytes including chimeric antigen receptor (CAR) gene delivery to T cells, a major breakthrough in cancer therapy. Yet, room for improvement remains, especially for the latest LV generations delivering genes selectively into T cell subtypes, a key requirement for in vivo CAR T cell generation. Toward improving gene transfer rates with these vectors, whole transcriptome analyses on human T lymphocytes are conducted after exposure to CAR-encoding conventional vectors (VSV-LV) and vectors targeted to CD8+ (CD8-LV) or CD4+ T cells (CD4-LV). Genes related to quiescence and antiviral restriction are found to be upregulated in CAR-negative cells exposed to all types of LVs. Down-modulation of various antiviral restriction factors, including the interferon-induced transmembrane proteins (IFITMs) is achieved with rapamycin as verified by mass spectrometry (LC-MS). Strikingly, rapamycin enhances transduction by up to 7-fold for CD8-LV and CD4-LV without compromising CAR T cell activities but does not improve VSV-LV. When administered to humanized mice, CD8-LV results in higher rates of green fluorescent protein (GFP) gene delivery. Also in vivo CAR T cell generation is improved in kinetics and tumor control, however to a moderate extent, leaving room for improvement by optimizing the rapamycin administration schedule. The data favor multi-omics approaches for improvements in gene delivery.

Gene therapy for inherited retinal diseases: exploiting new tools in genome editing and nanotechnology.

Inherited retinal diseases (IRDs) encompass a diverse group of genetic disorders that lead to progressive visual impairment and blindness. Over the years, considerable strides have been made in understanding the underlying molecular mechanisms of IRDs, laying the foundation for novel therapeutic interventions. Gene therapy has emerged as a compelling approach for treating IRDs, with notable advancements achieved through targeted gene augmentation. However, several setbacks and limitations persist, hindering the widespread clinical success of gene therapy for IRDs. One promising avenue of research is the development of new genome editing tools. Cutting-edge technologies such as CRISPR-Cas9 nucleases, base editing and prime editing provide unprecedented precision and efficiency in targeted gene manipulation, offering the potential to overcome existing challenges in gene therapy for IRDs. Furthermore, traditional gene therapy encounters a significant challenge due to immune responses to viral vectors, which remain crucial obstacles in achieving long-lasting therapeutic effects. Nanotechnology has emerged as a valuable ally in the quest to optimize gene therapy outcomes for ocular diseases. Nanoparticles engineered with nanoscale precision offer improved gene delivery to specific retinal cells, allowing for enhanced targeting and reduced immunogenicity. In this review, we discuss recent advancements in gene therapy for IRDs and explore the setbacks that have been encountered in clinical trials. We highlight the technological advances in genome editing for the treatment of IRDs and how integrating nanotechnology into gene delivery strategies could enhance the safety and efficacy of gene therapy, ultimately offering hope for patients with IRDs and potentially paving the way for similar advancements in other ocular disorders.

P26 enhances baculovirus gene delivery by modulating the mammalian antiviral response.

Poxins are poxviral proteins that act by degrading 2´3´-cGAMP, a key molecule of cGAS-STING axis that drives and amplifies the antiviral response. Previous works have described some poxin homologous among lepidopteran and baculoviral genes. In particular, P26, a poxin homologous from AcMNPV retains the 2´3´-cGAMP degradation activity in vitro. In this work, we demonstrated that the antiviral activity triggered by baculovirus was disrupted by the transient expression of P26 in murine and human cell lines, and the effect of this action is not only on IFN-β production but also on the induction of IFN-λ. Besides, we proved P26 functionality in a stable-transformed cell line where the protein was constitutively expressed, preventing the production of IFN-β induced by baculovirus and resulting in an improvement in the transduction efficiency by the attenuation of the antiviral activity. Finally, we incorporated P26 into budded virions by capsid display or passive incorporation, and the results showed that both strategies resulted in an improvement of 3-17 times in the efficiency of transgene expression in murine fibroblasts. Our results suggest that the incorporation of P26 to budded baculoviral vectors is a very promising tool to modulate negatively the innate antiviral cellular response and to improve the efficiency of gene delivery in mammalian cells. KEY POINTS: • P26 affects baculovirus-induced IFN-β and IFN-λ production in mammalian cells. • Murine fibroblasts expressing P26 are more susceptible to transduction by baculovirus. • Incorporation of P26 into the virion improves gene delivery efficiency of baculovirus.