Rapamycin enhances CAR-T control of HIV replication and reservoir elimination in vivo
Wenli Mu, … , Scott G. Kitchen, Anjie Zhen
Wenli Mu, … , Scott G. Kitchen, Anjie Zhen
Published February 11, 2025
Citation Information: J Clin Invest. 2025;135(7):e185489. https://doi.org/10.1172/JCI185489.
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Research Article AIDS/HIV Immunology Article has an altmetric score of 8

Rapamycin enhances CAR-T control of HIV replication and reservoir elimination in vivo

Abstract

Chimeric antigen receptor (CAR) T cell therapy shows promise for various diseases. Our studies in humanized mice and nonhuman primates demonstrate that hematopoietic stem cells (HSCs) modified with anti-HIV CAR achieve lifelong engraftment, providing functional antiviral CAR-T cells that reduce viral rebound after antiretroviral therapy (ART) withdrawal. However, T cell exhaustion due to chronic immune activation remains a key obstacle to sustained CAR-T efficacy, necessitating additional measures to achieve functional cure. We recently showed that low-dose rapamycin treatment reduced inflammation and improved anti-HIV T cell function in HIV-infected humanized mice. Here, we report that rapamycin improved CAR-T cell function both in vitro and in vivo. In vitro treatment with rapamycin enhanced CAR-T cell mitochondrial respiration and cytotoxicity. In vivo treatment with low-dose rapamycin in HIV-infected, CAR-HSC mice decreased chronic inflammation, prevented exhaustion of CAR-T cells, and improved CAR-T control of viral replication. RNA-sequencing analysis of CAR-T cells from humanized mice showed that rapamycin downregulated multiple checkpoint inhibitors and upregulated key survival genes. Mice treated with CAR-HSCs and rapamycin had delayed viral rebound after ART and reduced HIV reservoir compared with those treated with CAR-HSCs alone. These findings suggest that HSC-based anti-HIV CAR-T cells combined with rapamycin treatment are a promising approach for treating persistent inflammation and improving immune control of HIV replication.

Authors

Wenli Mu, Shallu Tomer, Jeffrey Harding, Nandita Kedia, Valerie Rezek, Ethan Cook, Vaibahavi Patankar, Mayra A. Carrillo, Heather Martin, Hwee Ng, Li Wang, Matthew D. Marsden, Scott G. Kitchen, Anjie Zhen

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Figure 3

Transcriptional signatures show reduced exhaustion markers and upregulation of memory- and survival-related signaling in CAR-T cells from rapamycin-treated mice.

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Transcriptional signatures show reduced exhaustion markers and upregulat...
(A) Humanized NSG-BLT mice with D1D2CAR41BB-modified HSCs were treated with rapamycin or vehicle for 2 weeks before necropsy. Afterward, splenocytes were isolated, GFP+ CAR cells were sorted, and bulk RNA sequencing was performed (n = 3 per group). (B) Representative flow cytometry analysis showing the gating strategy for sorting of GFP+ CAR single cells. (C and D) Principal component analysis (PCA) (C) and heatmap (D) showing the relative expression (z score) of the top 5,000 genes that were differentially expressed between the 2 populations of CAR-T cells derived from rapamycin-treated versus vehicle-treated CAR mice. Genes were divided into downregulated (green) and upregulated (pink) clusters by k-means clustering based on expression. (E) Box plot of log-normalized counts of genes important in T cell survival, activation, and exhaustion. Box plots show the interquartile range, median (line), and minimum and maximum (whiskers). (F) KEGG pathway analysis of differentially expressed genes among CAR-T cells between rapamycin-treated and vehicle-treated CAR mice. “GeneRatio” is the percentage of total DEGs in the given Gene Ontology term.