Abstract
BACKGROUND: Lentiviral vectors (LVVs) are used as a viral gene therapeutic and were derived from human immunodeficiency virus subtype 1 (HIV-1). LVVs are used to deliver and induce the stable expression of transgenes through genome integration. Current clinical LVV delivery systems do not include HIV-1 major accessory genes; however, critical structural and non-structural HIV-1 proteins are encoded by the 4-plasmid combination that composes the 3(rd) generation LVV transduction systems. LVVs use HIV-1-like mechanisms for viral genome integration and both transgene delivery and expression. LVVs rely on host cell machinery to transcribe and translate transgenes for either knocking down disease-causing genes and/or supplying functional genes in a targeted disease. LVVs integrate into host intronic and intergenic regions due to genomic accessibility, but there are no known biases toward specific target integration motifs. MAIN BODY: Investigation of LVV integration has uncovered the generation of chimeric LVV-host transcripts and altered host transcript splicing patterns. Several Food and Drug Administration (FDA)-approved LVV-derived therapies are used for treating diseases ranging from beta thalassemia to sickle cell anemia. An increasingly popular application of LVV is in the generation of chimeric antigen receptor (CAR) T cell therapies, which change and enhance T cell antigen specificity and effector function in liquid cancers. In November 2023, all CAR T cell therapies were placed under FDA investigation due to higher-than-expected rates of malignant transformation, hospitalization, and death in treated individuals. LVV integrations driving oncogene expression could be a cause for malignancy development. Current methods for resolving LVV integration patterns are technically limited by the sequencing approach applied allowing for only limited characterization of LVV integration profiles and altered host gene regulation. CONCLUSIONS: A comprehensive understanding of LVV integration and its consequences is necessary for understanding how these events influence host cell gene regulation and splicing, possibly identifying tunable variables for enhanced positive clinical outcomes. Here, we review the development of LVV systems, what is known about LVV integration patterns, technologies used to characterize patterns of LVV integration, and what is understood about the subsequent impact on host cell gene regulation and its potential linkage to patient malignancies.