Modifying CMV specific T cells with a novel bicistronic CD4-CAR/mac46 vector to target HIV

January 2022

archives@tulane.edu / Background: Human Immunodeficiency Virus-1 (HIV-1) has killed over 35 million and infects 1.8 million new people each year. Antiretroviral therapy (ART), although effective controlling plasma viremia and transmission, does not purge latent or persistent reservoirs necessary to eliminate infection, and must be maintained for life. It is thus imperative to discover therapeutics that provide both lifetime suppression of viral loads and depletion of viral reservoirs. Methods: To harness the immunosurveillance capacity of highly functional and persistent CMV-specific adaptive response, rhesus PBMCs were stimulated with rhCMV peptide pools (IE1, IE2, and pp65) to expand rhCMV-specific T cells. These cells were then genetically modified with retroviral vectors expressing a CD4 extracellular domain linked to T cell intracellular signaling domains that instruct CTL activity, converting them into HIV-specific effector cells. Vectors combine CD4 targeting with an maC46 fusion inhibitor to protect against viral entry. In a reversal of the critical step in the HIV viral lifecycle whereby virus targets new CD4+ host cells using its Env glycoprotein, these genetic modifications redirect host immune responses to target and kill Env expressing infected cells. We hypothesize that continuous stimulation of CD4-CAR T cells through their rhCMV-specific TCR will maintain activated T effector memory CTL capable of targeting HIV infected cells. Results: We find that autologous rhPBMCs can be expanded ex vivo with rhCMV peptides up to therapeutically relevant numbers for adoptive transfer. This rhCMV-specific T cell expansion enriches cells in a phenotype consistent with T effector memory differentiation. Following genetic modification and adoptive transfer, cells reach peak expansion at seven days post infusion into ART suppressed or unsuppressed SHIV infected Rhesus Macaques. We observe these cells capable of persisting in vivo for at least 2 years following reinfusion. Furthermore, these cells are maintained in vivo in an effector memory phenotype throughout the duration they were analyzed. Despite this, SHIV plasma viral loads remain unchanged. Conclusion: These studies establish use of rhCMV-specific T cells as an effective way to produce persistent genetically modified cells targeting SHIV. Future studies will need to further increase in vivo expansion, protection, and CTL activity as viral loads remain detectable. / 1 / Nathan Michel Johnson

CAR T cell Immunotherapy

HIV

Rhesus Macaque

Transcriptional states of CAR-T infusion relate to neurotoxicity: lessons from high-resolution single-cell SOM expression portraying

Loeffler-Wirth, Henry, Rade, Michael, Arakelyan, Arsen, Kreuz, Markus, Loeffler, Markus, Koehl, Ulrike, Reiche, Kristin, Binder, Hans

04 March 2024

Anti-CD19 CAR-T cell immunotherapy is a hopeful treatment option for patients with B cell lymphomas, however it copes with partly severe adverse effects like neurotoxicity. Single-cell resolved molecular data sets in combination with clinical parametrization allow for comprehensive characterization of cellular subpopulations, their transcriptomic states, and their relation to the adverse effects. We here present a re-analysis of single-cell RNA sequencing data of 24 patients comprising more than 130,000 cells with focus on cellular states and their association to immune cell related neurotoxicity. For this, we developed a single-cell data portraying workflow to disentangle the transcriptional state space with single-cell resolution and its analysis in terms of modularly-composed cellular programs. We demonstrated capabilities of single-cell data portraying to disentangle transcriptional states using intuitive visualization, functional mining, molecular cell stratification, and variability analyses. Our analysis revealed that the T cell composition of the patient’s infusion product as well as the spectrum of their transcriptional states of cells derived from patients with low ICANS grade do not markedly differ from those of cells from high ICANS patients, while the relative abundancies, particularly that of cycling cells, of LAG3-mediated exhaustion and of CAR positive cells, vary. Our study provides molecular details of the transcriptomic landscape with possible impact to overcome neurotoxicity.

info:eu-repo/classification/ddc/610

ddc:610