Competitive binding and molecular crowding regulate the cytoplasmic interactome of non-viral polymeric gene delivery vectors

In contrast to the processes controlling the complexation, targeting and uptake of polycationic gene delivery vectors, the molecular mechanisms regulating their cytoplasmic dissociation remains poorly understood. Upon cytosolic entry, vectors become exposed to a complex, concentrated mixture of molecules and biomacromolecules. In this report, we characterise the cytoplasmic interactome associated with polycationic vectors based on poly(dimethylaminoethyl methacrylate) (PDMAEMA) and poly(2-methacrylolyloxyethyltrimethylammonium chloride) (PMETAC) brushes. To quantify the contribution of different classes of low molar mass molecules and biomacromolecules to RNA release, we develop a kinetics model based on competitive binding. Our results identify the importance of competition from highly charged biomacromolecules, such as cytosolic RNA, as a primary regulator of RNA release. Importantly, our data indicate the presence of ribosome associated proteins, proteins associated with translation and transcription factors that may underly a broader impact of polycationic vectors on translation. In addition, we bring evidence that molecular crowding modulates competitive binding and demonstrate how the modulation of such interactions, for example via quaternisation or the design of charge-shifting moieties, impacts on the long-term transfection efficiency of polycationic vectors. Understanding the mechanism regulating cytosolic dissociation will enable the improved design of cationic vectors for long term gene release and therapeutic efficacy.

I Am Here: It Took a Global Village

The saying “It takes a village to raise a child” has never been truer than in my case. This autobiographical article documents my growing up and working on three different continents and my influencers along the way. Born in a village in Nigeria, West Africa, I spent the first 12 years of life with my grandmother living in a mud house and attending a village primary school. I walked barefoot to school every day, learned to read, and wrote on a chalk slate. At the age of 13, I moved to my second “village,” London, England. In secondary school my love of science began to blossom. I attained a double major in chemistry and human biology from the University of Hertfordshire and a PhD in biophysics from the University of London, with a research project aimed at designing anticancer agents. I was mentored by Terence Jenkins and Stephen Neidle. For my postdoctoral training, I crossed the ocean again, to the United States, my third “village.” In Michael Rossmann's group at Purdue University, my love for viruses was ignited. My independent career in structural virology began at Warwick University, England, working on pathogenic single-stranded DNA packaging viruses. In 2020, I am a full professor at the University of Florida. Most of my research is focused on the adeno-associated viruses, gene delivery vectors. My list of mentors has grown and includes Nick Muzyczka. Here, the mentee has become the mentor, and along the way, we attained a number of firsts in the field of structural virology and contributed to the field at the national and international stages.

Dual Promoters Improve the Rescue of Recombinant Measles Virus in Human Cells

Reverse genetics is a technology that allows the production of a virus from its complementary DNA (cDNA). It is a powerful tool for analyzing viral genes, the development of novel vaccines, and gene delivery vectors. The standard reverse genetics protocols are laborious, time-consuming, and inefficient for negative-strand RNA viruses. A new reverse genetics platform was established, which increases the recovery efficiency of the measles virus (MV) in human 293-3-46 cells. The novel features compared with the standard system involving 293-3-46 cells comprise (a) dual promoters containing the RNA polymerase II promoter (CMV) and the bacteriophage T7 promoter placed in uni-direction on the same plasmid to enhance RNA transcription; (b) three G nucleotides added just after the T7 promoter to increase the T7 RNA polymerase activity; and (c) two ribozymes, the hairpin hammerhead ribozyme (HHRz), and the hepatitis delta virus ribozyme (HDVrz), were used to cleavage the exact termini of the antigenome RNA. Full-length antigenome cDNA of MV of the wild type IC323 strain or the vaccine AIK-C strain was inserted into the plasmid backbone. Both virus strains were easily rescued from their respective cloned cDNA. The rescue efficiency increased up to 80% compared with the use of the standard T7 rescue system. We assume that this system might be helpful in the rescue of other human mononegavirales.

Development and Characterization of High Efficacy Cell-Penetrating Peptide via Modulation of the Histidine and Arginine Ratio for Gene Therapy

Cell-penetrating peptides (CPPs), as non-viral gene delivery vectors, are considered with lower immunogenic response, and safer and higher gene capacity than viral systems. In our previous study, a CPP peptide called RALA (arginine rich) presented desirable transfection efficacy and owns a potential clinic use. It is believed that histidine could enhance the endosome escaping ability of CPPs, yet RALA peptide contains only one histidine in each chain. In order to develop novel superior CPPs, by using RALA as a model, we designed a series of peptides named HALA (increased histidine ratio). Both plasmid DNA (pDNA) and siRNA transfection results on three cell lines revealed that the transfection efficacy is better when histidine replacements were on the C-terminal instead of on the N-terminal, and two histidine replacements are superior to three. By investigating the mechanism of endocytosis of the pDNA nanocomplexes, we discovered that there were multiple pathways that led to the process and caveolae played the main role. During the screening, we discovered a novel peptide-HALA2 of high cellular transfection efficacy, which may act as an exciting gene delivery vector for gene therapy. Our findings also bring new insights on the development of novel robust CPPs.

Current Designs of Polymeric Platforms towards the Delivery of Nucleic Acids inside the Cells with Focus on Polyethylenimine

Background: Gene delivery is a promising technology for treating diseases linked to abnormal gene expression. Since nucleic acids are the therapeutic entities in such approach, a transfecting vector is required because the macromolecules are not able to efficiently enter the cells by themselves. Viral vectors have been evidenced to be highly effective in this context; however, they suffer from fundamental drawbacks, such as the ability to stimulate immune responses. The development of synthetic vectors has accordingly emerged as an alternative. Objectives: Gene delivery by using non-viral vectors is a multi-step process that poses many challenges, either regarding the extracellular or intracellular media. We explore the delivery pathway and afterwards, we review the main classes of non-viral gene delivery vectors. We further focus on the progresses concerning polyethylenimine-based polymer-nucleic acid polyplexes, which have emerged as one of the most efficient systems for delivering genetic material inside the cells. Discussion: The complexity of the whole transfection pathway, along with a lack of fundamental understanding, particularly regarding the intracellular trafficking of nucleic acids complexed to non-viral vectors, probably justifies the current (beginning of 2021) limited number of formulations that have progressed to clinical trials. Truly, successful medical developments still require a lot of basic research. Conclusion: Advances in macromolecular chemistry and high-resolution imaging techniques will be useful to understand fundamental aspects towards further optimizations and future applications. More investigations concerning the dynamics, thermodynamics and structural parameters of polyplexes would be valuable since they can be connected to the different levels of transfection efficiency hitherto evidenced.

Nonviral gene delivery vectors for transfection of the CAR gene for CAR-T cell therapy

The introduction of the CAR gene via retrovirus is the most widely used and most successful technique for CAR-T cell therapy. However, the limitations and risks associated with viral gene therapy continue to motivate the development of nonviral gene delivery technologies that are potentially safer, less expensive, and quicker. In terms of safety and efficacy, electroporation has emerged as the most promising non-viral technology, albeit more optimization testing and clinical trials are required before it can be directly compared to retroviral CAR gene delivery techniques. But these findings suggest that non-viral gene delivery to T cells (and other related cells, such as natural killer cells) is feasible and is quickly emerging as a viable alternative to CAR-T cell therapy and other gene therapies.

Gene Therapy for Lysosomal Storage Disorders: Ongoing Studies and Clinical Development

Rare monogenic disorders such as lysosomal diseases have been at the forefront in the development of novel treatments where therapeutic options are either limited or unavailable. The increasing number of successful pre-clinical and clinical studies in the last decade demonstrates that gene therapy represents a feasible option to address the unmet medical need of these patients. This article provides a comprehensive overview of the current state of the field, reviewing the most used viral gene delivery vectors in the context of lysosomal storage disorders, a selection of relevant pre-clinical studies and ongoing clinical trials within recent years.

Rapid Characterization of AAV gene therapy vectors by Mass Photometry

Recombinant adeno-associated viruses (rAAV) are extensively used as gene delivery vectors in clinical studies, and several rAAV based treatments have already been approved. Significant progress has been made in rAAV manufacturing, and large-scale vector production and purification methods have been developed. However, a better and more precise capsid characterization techniques are still needed to guarantee the purity and safety of the rAAV preparations. A recently developed single-molecule technique, mass photometry (MP), measures mass distributions of biomolecules with high resolution and sensitivity. Here we explore applications of MP for the characterization of capsid fractions. We demonstrate that MP is able to resolve and quantify not only empty and full-genome containing capsid populations, but also identify the partially packaged capsid impurities. MP data accurately measures full and empty capsid ratios, and can be used to estimate the size of the encapsidated genome. MP distributions provide information on sample heterogeneity and on the presence of aggregates. Current analytical techniques used to characterize rAAV preparations are susceptible to background signals, have limited accuracy, or are time-consuming and require a large amount of material. MP can analyze sub-picomole quantities of sample, and data can be obtained and analyzed within minutes. This method provides a simple, robust, and effective tool to monitor physical attributes of rAAV vectors.

Substance P Containing Peptide Gene Delivery Vectors for Specifically Transfecting Glioma Cells Mediated by Neurokinin-1 Receptor

Gene therapy provides a promising treatment for glioblastoma multiforme, which mainly depends on two keys, crossing the blood brain barrier (BBB) effectively and transfecting target cells selectively. In this work,...

In silico prediction of the in vitro behavior of polymeric gene delivery vectors

The authors describe a novel screening tool to test bench non-viral transfectants enabling to foresee the most suitable conditions for the complexation of relevant siRNA-polycation assemblies.