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Adeno-associated virus (AAV) is widely regarded as a leading vector for gene therapy, underscored by clinical successes such as Luxturna and Zolgensma. However, efficient gene delivery to hard-to-transduce tissues—including the retina, deep skeletal muscle, and the central nervous system—remains a significant challenge, limited by structural barriers, preexisting immunity, and dose-dependent toxicities. This review systematically outlines recent advances in overcoming these delivery bottlenecks. We delve into four key strategic areas: (i) capsid engineering (
Adeno-associated virus (AAV) vectors are promising platforms used in a growing number of approved gene therapy (GT) products across diverse therapeutic areas. Due to the potential safety and efficacy concerns associated with AAV-based immune responses, patients with pre-existing anti-AAV antibodies (Abs) are routinely excluded from GT trials to prevent treatment of patients who are hypothesized to have potentially higher risk and/or little or no benefit. However, the exclusion of seropositive patients without prior GT exposure is not based on data-driven Ab titer cut-offs, and diagnostics to identify levels of pre-existing immunity have not been standardized, precluding data generation that would substantiate or reject this hypothesis. There are also significant gaps in clinical data comparing the impact of pre-existing immunity with treatment-induced immune responses for a variety of disease states. This review aims to address these gaps by examining the impact of pre-existing anti-AAV Abs on the safety and efficacy of approved and failed GT products and ongoing clinical trials. Together, these data suggest that pre-existing immunity may not be the principal determinant of GT success. Therefore, to expand the number of patients eligible for treatment, novel AAV GTs should be optimized to mitigate against the effects of anti-AAV Abs and avoid the need for exclusionary screening; in turn, including both seronegative and seropositive patients in clinical trials will enable characterization of the clinical relevance of anti-AAV Abs. Strategies to prevent an undesirable immune response to GT, including immunosuppressive regimens and modifications to GT manufacturing, design and delivery, are presented for consideration in future GT trials.
Oncolytic viruses are being investigated as therapeutic agents in cancer, yet their mechanisms of entry into tumor cells remain incompletely understood. We previously showed that SG33, a veterinary vaccinal strain derived from a pathogenic myxoma virus, displays oncolytic activity in preclinical models of pancreatic ductal adenocarcinoma (PDAC). Here, we investigated the entry pathways of SG33 into primary PDAC-derived cultures. We found that macropinocytosis, an endocytic process frequently upregulated in PDAC, contributes to SG33 uptake. Moreover, SG33 infection itself induced macropinocytosis in a subset of primary PDAC cultures. Mechanistic studies revealed that phosphatidylserine exposed on the viral envelope promotes SG33 internalization through apoptotic mimicry. In PDAC cultures lacking detectable macropinocytosis, SG33 employed clathrin-mediated endocytosis as an alternative entry route. These findings provide the first insights into the entry mechanisms of SG33 into PDAC-derived cells and indicate that this virus can utilize distinct endocytic pathways depending on the cellular context.
Lentiviral vectors are widely used in both biological research and therapeutic applications. Accurate and reliable quantification is essential for their effective use, yet existing methods are often technically demanding and time-consuming. Here, we describe a simple and robust approach to measure lentiviral titers by quantifying viral genomic RNA with nucleic acid–binding dyes. We first evaluated several newly developed commercially available fluorescent dyes for their ability to detect RNA and DNA, identifying SYBR Green II and SYBR Gold as the most sensitive for RNA, with detection limits in the low-nanogram range. We further observed that SYBR Green II readily stained nucleic acids in live cells, whereas SYBR Gold was only partially membrane-permeable. Based on these findings, we developed a quantification method combining SYBR Green II with benzonase to selectively detect encapsidated lentiviral RNA. This assay yielded results consistent with those obtained by enzyme-linked immunosorbent assays. Importantly, this SYBR Green II–based method is rapid (<60 min), reliable, and cost-effective, making it a practical tool for titering lentiviral vectors.
Type 1 regulatory T (Tr1) cells are CD4+/FoxP3–/CD49b+/LAG-3+ regulatory T cells that are induced in the periphery following chronic exposure to antigen in the presence of IL-10. Activated Tr1 cells secrete high quantities of anti-inflammatory cytokines, especially IL-10, and enforce robust bystander immune suppression, rendering them particularly attractive for adoptive cell therapy of autoimmune and autoinflammatory diseases. Here we introduce retroviral transduction of human CD4+ T cells with membrane-attached IL-10 (memIL-10) or memIL-10/CAR as a new method for generating large cell populations of high purity, stability, and antigen specificity displaying the main phenotypic and functional characteristics of Tr1 cells.