Humanized Immune System Research Articles

Overexpression of FBP1 enhances dendritic cell activation and maturation by inhibiting glycolysis and promoting the secretion of IL33 in lung adenocarcinoma

Fructose 1,6-diphosphatase 1 (FBP1) is an enzyme involved in gluconeogenesis and glycolysis inhibition. Dendritic cells (DCs) are antigen-presenting cells, and antigens presented to T cells activate the immune response. FBP1 inhibits the development of several tumors, and high FBP1 expression inhibits the proliferation, migration, and invasion of lung cancer cells. However, the mechanism through which FBP1 mediates the tumor immune microenvironment is unclear. This study mainly analyzed the role of FBP1 in regulating the function of DCs through metabolic reprogramming and immune microenvironment using in vitro and in vivo experiments. The positive association of FBP1 with DCs was found by bioinformatic analysis. The in vitro experiments revealed that the extracellular acidification rate and lactate level were lower in the FBP1 overexpression cells than in the control cells and that the lower lactate level reduced the inhibition of DC function. In addition, high FBP1 expression promoted the secretion of IL33 by activating the cGAS/STING/NF-κB/IL33 pathway, which was identified and verified via high-throughput sequencing and in vitro experiments. FBP1 activated the cGAS/STING pathway by increasing the degree of DNA damage, as revealed by the level of γH2AX and comet assay. IL33 enhanced the expression of the DC costimulatory molecules CD86 and HLA-DR as well as that of the functional factor IL-1β. The results demonstrated that FBP1 promoted the activation and maturation of DCs by inhibiting glycolysis and promoting the secretion of IL33 as well as by further activating the function of CD8+T cells. Finally, the humanized immune system mouse models confirmed the above role of FBP1. Thus, FBP1 may serve as a new target to cure lung adenocarcinoma, and IL33 may improve the efficiency of immune therapy in lung adenocarcinoma.

T-cell responses in colorectal peritoneal metastases are recapitulated in a humanized immune system mouse model.

The occurrence of peritoneal metastasis (PM) in patients with colorectal cancer (CRC) has a dismal prognosis. There is often limited response to systemic- and immunotherapy, even in microsatellite unstable (MSI) CRC. To overcome therapy resistance, it is critical to understand local immune environment in the peritoneal cavity, and to develop models to study anti-tumor immune responses. Here, we defined the peritoneal immune system (PerIS) in PM-CRC patients and evaluate the pre-clinical potential of a humanized immune system (HIS) mouse model for PM-CRC. We studied the human PerIS in PM-CRC patients (n=20; MSS 19/20; 95%) and in healthy controls (n=3). HIS mice (NODscid gamma background; n=18) were generated, followed by intraperitoneal injection of either saline (HIS control; n=3) or human MSS/MSI CRC cell lines HUTU80, MDST8 and HCT116 (HIS-PM, n=15). Immune cells in peritoneal fluid and peritoneal tumors were analyzed using cytometry by time of flight (CyTOF). The human and HIS mouse homeostatic PerIS was equally populated by NK cells and CD4+- and CD8+ T cells, however differences were observed in macrophage and B cell abundance. In HIS mice, successful peritoneal engraftment of both MSI and MSS tumors was observed (15/15; 100%). Both in human PM-CRC and in the HIS mouse PM-CRC model, we observed that MSS PM-CRC triggered a CD4+ Treg response in the PerIS, while MSI PM-CRC drives CD8+ TEMs responses. In conclusion, T cell responses in PM-CRC in HIS mice mirror those in human PM-CRC, making this model suitable to study antitumor T cell responses in PM-CRC.

Therapeutic Modulation of Arginase with nor-NOHA Alters Immune Responses in Experimental Mouse Models of Pulmonary Tuberculosis including in the Setting of Human Immunodeficiency Virus (HIV) Co-Infection.

L-arginine metabolism is strongly linked with immunity to mycobacteria, primarily through the antimicrobial activity of nitric oxide (NO). The potential to modulate tuberculosis (TB) outcomes through interventions that target L-arginine pathways are limited by an incomplete understanding of mechanisms and inadequate in vivo modeling. These gaps in knowledge are compounded for HIV and Mtb co-infections, where activation of arginase-1 due to HIV infection may promote survival and replication of both Mtb and HIV. We utilized in vitro and in vivo systems to determine how arginase inhibition using Nω-hydroxy-nor-L-arginine (nor-NOHA) alters L-arginine pathway metabolism relative to immune responses and disease outcomes following Mtb infection. Treatment with nor-NOHA polarized murine macrophages (RAW 264.7) towards M1 phenotype, increased NO, and reduced Mtb in RAW macrophages. In Balb/c mice, nor-NOHA reduced pulmonary arginase and increased the antimicrobial metabolite spermine in association with a trend towards reduced Mtb CFU in lung. In humanized immune system (HIS) mice, HIV infection increased plasma arginase and heightened the pulmonary arginase response to Mtb. Treatment with nor-NOHA increased cytokine responses to Mtb and Mtb/HIV in lung tissue but did not significantly alter bacterial burden or viral load. Our results suggest that L-arginine pathway modulators may have potential as host-directed therapies to augment antibiotics in TB chemotherapy.

Transcriptome profiling and characterization of peritoneal metastasis ovarian cancer xenografts in humanized mice

Although immunotherapy has not yet been as successful in ovarian cancer (OC), it remains a potential therapeutic strategy. Preclinical models of OC are necessary to evaluate the efficacy of immuno-oncology (IO) drugs targeting human immune components but have been underutilized. Developing mouse models with a humanized (Hu) immune system can help understand the human immune response to IO drugs which have demonstrated limited effectiveness in OC patients. We established OC xenograft Hu-mouse models by intraperitoneally injecting luciferase-expressing SKOV-3 Luc and OVCAR-3 Luc OC cells into CD34+ Hu-mice. Tumor growth was monitored through bioluminescence imaging (BLI). In the SKOV-3 Luc Hu-mouse model, we assessed the efficacy of PD-1 blockade with pembrolizumab. We observed the presence of human lymphocyte and myeloid cell subsets within the tumors, lymph nodes, blood, and spleens in these models. Notably, these tumors exhibited a high prevalence of tumor-infiltrating macrophages. Furthermore, we identified HDAC class I target genes, and genes associated with epithelial-mesenchymal transition (EMT) and fibroblasts in the tumors of Hu-mice treated with pembrolizumab. Our xenograft Hu-mouse model of OC provides a valuable tool for investigating the efficacy of IO drugs. The insights gained from this model offer useful information to explore potential mechanisms associated with unresponsive anti-PD-1 treatment in OC.

Abstract 5337: Profiling of human CD34+ donors in a myeloid-supportive HIS model provides increased predictability and facilitates study design for evaluation of immuno-oncology therapeutics

Abstract Background: Humanized immune system (HIS) mice are critical immuno-oncology tools for in vivo evaluation of therapeutic target engagement and efficacy. HIS mice require a human donor source of CD34+ hematopoietic stem cells to provide the human immune cell system. However, variance across donors complicates study design and hypothesis testing. To determine if parameters critical to drug discovery are consistent across batches of HIS mice from the same donor, we evaluated two independent cohorts of human tumor xenograft-bearing mice made using a common set of five different CD34+ cell donors. Our study included evaluation of tumor growth kinetics, human immune reconstitution and phenotype, and the pharmacokinetics and anti-tumor efficacy of a therapeutic monoclonal antibody directed against a human target expressed on tumor-associated macrophages (TAMs). Method: HIS NOG-EXL (huNOG-EXL) mice were created using CD34+ cells from five donors in two independent cohorts (~12 weeks apart). Baseline immune reconstitution in blood was assessed at 10 weeks post engraftment. MDA-MB-231 cells were inoculated bilaterally and mice were randomized into groups for immune profiling, pharmacokinetics, and efficacy studies. Body weight, clinical observations, endogenous hIgG levels, and tumor growth were measured. For efficacy, tumors grew to ~100 mm3 and mice were dosed intraperitoneally every five days (6 doses total). Separate cohorts of mice were used for immune phenotyping and the single-dose PK study. Results: Donor consistency was seen for some of the parameters assessed but not all. The overall health outcomes for a given donor appeared to have an impact on the consistency of important parameters (e.g. efficacy). Donors that had poor health outcomes (body condition scores [BCS] <3) showed less consistency than those that experienced good (BCS=3) outcomes. The health trajectory, peripheral human immune cell engraftment, and PK profiles were similar across experiments for a given donor. Total human immune cell infiltration in tumors was similar across experiments, but there were notable shifts in immune cell composition. Whereas mice in the first cohort showed a dominant TAM phenotype within the tumor (~>50% of all hCD45+ cells), mice across donors in the second cohort had reduced TAMs and corresponding increases in several T cell subsets. Efficacy was consistent in donors with good health outcomes (Donors 1 and 4) and was inconsistent in those with poor outcomes (Donors 3 and 5). Conclusion: Our study demonstrates that a return-to-donor approach can provide information that is reproducible across cohorts to help build a donor profile. An understanding of this profile should afford greater predictability and facilitate study design for drug discovery applications. Citation Format: Janell R. Richardson, Megan M. MacBride, Esther Andino, Emily Sack, Nicholas Smith, Po Y. Ho, Fang Xiao, Katelynn A. McEachin, David T. Omstead, Rachel Grgich, Michael N. Alonso, Justin A. Kenkel, Shelley E. Ackerman. Profiling of human CD34+ donors in a myeloid-supportive HIS model provides increased predictability and facilitates study design for evaluation of immuno-oncology therapeutics [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2024; Part 1 (Regular Abstracts); 2024 Apr 5-10; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2024;84(6_Suppl):Abstract nr 5337.

Abstract 5334: Humanization of NOG mice and next-generation NOG strains to induce lineage-specific differentiation of immune cells for assessment of novel immune cell therapies, check point inhibitors, and immune cell engagers for translational immuno-oncology research

Abstract Background: The preclinical evaluation of novel immune therapies requires humanized immune system (HIS) mouse models. In previous studies we have demonstrated that either peripheral blood mononuclear cells (PBMC), subsets of PBMCs like T and NK cells or CD34+ hematopoietic stem cells (HSC) can be used to establish a HIS model. With the development of next-generation NOG mice, lineage-specific differentiation of immune cell sub-populations of interest can be supported. Transplantation of cell line-derived (CDX) or patient-derived (PDX) tumor xenografts on HIS mice provides a full model for human tumors for the investigation of checkpoint inhibitors (CPI), as well as novel cell therapies and immune cell engagers. Methods: HSC-humanized mice were generated by i.v. transplantation of CD34+ stem cells to immunodeficient mice. For humanization, NOG mice and next-generation NOG strains were used: NOG, NOG-EXL, hIL-2 NOG, hIL-6 NOG and FcResolv™ NOG mice were compared to each other for lineage-specific differentiation using single donors or a mixed HSC donor pool. Engraftment of immune cells was monitored by FACS analysis of blood every four weeks. In humanized NOG mice, CDX and PDX from different entities were s.c. transplanted and used to evaluate CPI. Results: Humanized hIL-2 NOG mice showed significantly decreased survival after HSC transplantation in comparison to the other mouse strains and had to be sacrificed within the first 6-8 weeks after HSC transplantation. In the other mouse strains, transplanted HSCs engrafted and differentiated mainly into B and T cells. NOG-EXL mice displayed the highest engraftment, with up to 80% of human cells in the blood, including a higher portion of myeloid cells. In humanized hIL-6 NOG mice a higher portion of monocytes could be determined. FcResolv™ NOG mice lack murine Fc gamma receptors in order to reduce confounding interactions between residual murine immune cells and antibody-based therapies, and they engraft and differentiate human HSCs similarly to the parent NOG strain. In humanized NOG mice, selected CDX and PDX tumors successfully engrafted without significant differences in tumor growth compared to non-humanized mice. CPI treatments induced tumor growth delay in selected models. Conclusions: Next-generation NOG mouse strains are characterized by a lineage-specific differentiation of immune cells depending on integrated human cytokines. Furthermore, we established a human tumor-immune-cell model for NOG mice using different entities of CDX or PDX in combination with CPI. Our human tumor-immune cell models allow preclinical translational studies on tumor immune biology as well as evaluation of new therapies, drug combinations and biomarker identification and validation. Citation Format: Maria Stecklum, Louise Baskin, Jens Hoffmann. Humanization of NOG mice and next-generation NOG strains to induce lineage-specific differentiation of immune cells for assessment of novel immune cell therapies, check point inhibitors, and immune cell engagers for translational immuno-oncology research [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2024; Part 1 (Regular Abstracts); 2024 Apr 5-10; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2024;84(6_Suppl):Abstract nr 5334.

Abstract 4187: Transcriptome profiling and characterization of peritoneal metastasis ovarian cancer xenografts in humanized mice

Abstract Background: Although immunotherapy has not yet been as successful in ovarian cancer (OC), it remains a potential therapeutic strategy. Preclinical models of OC are necessary to evaluate the efficacy of immuno-oncology (IO) drugs targeting human cancer and immune components but have been underutilized. Developing mouse models with a humanized (Hu) immune system can help understand the human immune response to IO drugs, including immune checkpoint inhibitors (ICIs), which have demonstrated limited effectiveness in OC patients. Methods: We established OC xenograft Hu-mouse models by intraperitoneally injecting luciferase-expressing SKOV-3 Luc and OVCAR-3 Luc OC cells into CD34+ Hu-mice. Tumor growth was monitored through bioluminescence imaging (BLI). We assessed the efficacy of PD-1 blockade with pembrolizumab in the SKOV-3 Luc Hu-mouse model. The immune profiles of the tumors were characterized using colorimetric immunostaining and flow cytometry. Additionally, we analyzed RNA-seq data to investigate the gene expression signature of pembrolizumab refractory tumors. Results: We confirmed tumor development in both OC cell lines within CD34+ Hu-mice. In these models, human lymphocyte and myeloid cell subsets were present in the tumors, draining lymph nodes, blood, and spleens. The SKOV-3 Luc tumor-bearing Hu-mice did not respond to pembrolizumab monotherapy. These tumors exhibited a high presence of tumor-infiltrating macrophages. Tumors in Hu-mice unresponsive to pembrolizumab showed a lower abundance of CD8+ T-cells, memory B cells, plasma cells, and a higher proportion of naïve M0 macrophages and mast cells compared to the PBS control. Furthermore, we identified 43 significantly enriched gene sets in these tumors. The differentially expressed genes (DEGs) were predominantly enriched in HDAC class I, RB1, KLF1/3, TCF21, MYD88, SMARCE1 target genes, and genes associated with epithelial-mesenchymal transition (EMT) and fibroblasts. Conclusion: Our xenograft Hu-mouse model of OC provides a valuable tool for investigating the efficacy of IO drugs. The insights gained from this model offer potential avenues to explore mechanisms of resistance to PD-1/PD-L1 blockade in OC. Citation Format: Sung Wan Kang, Ji-young Lee, Ok-Ju Kang, Yong-Man Kim, Eun Kyung Choi, Shin-Wha Lee. Transcriptome profiling and characterization of peritoneal metastasis ovarian cancer xenografts in humanized mice [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2024; Part 1 (Regular Abstracts); 2024 Apr 5-10; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2024;84(6_Suppl):Abstract nr 4187.

RCAd-LTH-shPD-L1, a double-gene recombinant oncolytic adenovirus with enhanced antitumor immunity, increases lymphocyte infiltration and reshapes the tumor microenvironment

BackgroundWith the successful development of modern immunotherapy, immune checkpoint inhibitors (ICIs) are currently considered potential therapeutic options for patients with cancer. However, the therapeutic potential of ICIs in human cancer...

Abstract A005: Preclinical evaluation of novel immune cell therapies, check point inhibitors, and immune cell engagers in humanized mouse models

Abstract Background The preclinical evaluation of novel immune therapies requires humanized mouse models with functional human immune cells. In previous studies we have demonstrated, that either peripheral blood mononuclear cells (PBMC), subsets of PBMCs like T- and NK-cells or hematopoietic stem cells (HSC) can be used to establish a humanized immune system with functional T-, B-, and NK cells, as well as monocytes and dendritic cells in immunodeficient mice. By xenotransplantation of cell-line-derived (CDX) or patient-derived (PDX) tumors on humanized mice, we successfully generated a full human tumor-immune-cell model for different disease entities. Finally, we validated the functionality of these models using checkpoint inhibitors like Ipilimumab (Ipi), Nivolumab (Nivo), Pembrolizumab (Pembro), cell therapies, and immune cell engagers. Methods HSC-humanized mice were generated by i.v. transplantation of CD34+ stem cells to immunodeficient 1st and 2nd generation NOG mice. Engraftment of immune cells was monitored by FACS analysis of blood samples. PBMC or isolated T- or NK-cell preparations were used to humanize mice by single or multiple i.v. injections. CDX and PDX from different entities were s.c. (i.e. lymphoma) and/or i.v. (leukemia) transplanted on those humanized mice. Tumor growth of orthotopic models was followed up by BLI measurement. Blood and tumor samples were analysed by for immune cell infiltration and activation. Results The transplanted HSCs engrafted in mice and established a functional human immune system with proliferation and differentiation. The 2nd generation NOG mice are showing an increased total engraftment and lineage specific differentiation of cells. The selected CDX and PDX tumors successfully engrafted on humanized mice without significant differences in tumor growth compared to non-humanized mice. Check point inhibitor treatments (Ipi, Nivo, or Pembro) induced tumor growth delay in selected models. BLI measurement is a suitable method to follow up systemic disease models and treatment effects over time. We identified a set of CDX and PDX models without interference with parallel injection of PBMC, T- or NK-cell preparations for the evaluation of immune cell engagers and other cell therapies. Conclusions We established human tumor-immune-cell models of different entities using CDX or PDX in combination with different donor derived immune cell subsets as effector cells. We demonstrated successful engraftment of HSC on different immunodeficient mouse strains, generating mice with a functional human hematopoiesis. These models have been successfully used for preclinical evaluation of novel check point inhibitors, cell therapies and immune cell engagers. Our human tumor-immune-cell models allow preclinical translational research on tumor immune biology as well as evaluation of new therapies, drug combinations, as well as biomarker identification and validation in subcutaneous and orthotopic models. Citation Format: Maria Stecklum, Annika Wulf-Goldenberg, Bernadette Brzezicha, Joshua Alcaniz, Glenn Smits, Wolfgang Walther, Jens Hoffmann. Preclinical evaluation of novel immune cell therapies, check point inhibitors, and immune cell engagers in humanized mouse models [abstract]. In: Proceedings of the AACR-NCI-EORTC Virtual International Conference on Molecular Targets and Cancer Therapeutics; 2023 Oct 11-15; Boston, MA. Philadelphia (PA): AACR; Mol Cancer Ther 2023;22(12 Suppl):Abstract nr A005.

Progress, implications, and challenges in using humanized immune system mice in CAR-T therapy-Application evaluation and improvement.

In recent years, humanized immune system (HIS) mice have been gradually used as models for preclinical research in pharmacotherapies and cell therapies with major breakthroughs in tumor and other fields, better mimicking the human immune system and the tumor immune microenvironment, compared to traditional immunodeficient mice. To better promote the application of HIS mice in preclinical research, we selectively summarize the current prevalent and breakthrough research and evaluation of chimeric antigen receptor (CAR) -T cells in various antiviral and antitumor treatments. By exploring its application in preclinical research, we find that it can better reflect the actual clinical patient condition, with the advantages of providing high-efficiency detection indicators, even for progressive research and development. We believe that it has better clinical patient simulation and promotion for the updated design of CAR-T cell therapy than directly transplanted immunodeficient mice. The characteristics of the main models are proposed to improve the use defects of the existing models by reducing the limitation of antihost reaction, combining multiple models, and unifying sources and organoid substitution. Strategy study of relapse and toxicity after CAR-T treatment also provides more possibilities for application and development.

HTLV-1 Hbz protein, but not hbz mRNA secondary structure, is critical for viral persistence and disease development.

Human T-cell leukemia virus type 1 (HTLV-1) is the etiologic cause of adult T-cell leukemia/lymphoma (ATL) and encodes a viral oncoprotein (Hbz) that is consistently expressed in asymptomatic carriers and ATL patients, suggesting its importance in the development and maintenance of HTLV-1 leukemic cells. Our previous work found Hbz protein is dispensable for virus-mediated T-cell immortalization but enhances viral persistence. We and others have also shown that hbz mRNA promotes T-cell proliferation. In our current studies, we evaluated the role of hbz mRNA on HTLV-1-mediated immortalization in vitro as well as in vivo persistence and disease development. We generated mutant proviral clones to examine the individual contributions of hbz mRNA, hbz mRNA secondary structure (stem-loop), and Hbz protein. Wild-type (WT) and all mutant viruses produced virions and immortalized T-cells in vitro. Viral persistence and disease development were also evaluated in vivo by infection of a rabbit model and humanized immune system (HIS) mice, respectively. Proviral load and sense and antisense viral gene expression were significantly lower in rabbits infected with mutant viruses lacking Hbz protein compared to WT or virus with an altered hbz mRNA stem-loop (M3 mutant). HIS mice infected with Hbz protein-deficient viruses showed significantly increased survival times compared to animals infected with WT or M3 mutant virus. Altered hbz mRNA secondary structure, or loss of hbz mRNA or protein, has no significant effect on T-cell immortalization induced by HTLV-1 in vitro; however, the Hbz protein plays a critical role in establishing viral persistence and leukemogenesis in vivo.

ARID1A deficiency in triple-negative breast cancer induces adaptive immune resistance and sensitivity to immune checkpoint inhibitors.

1088 Background: Adaptive immune resistance (AIR) is pivotal to triple-negative breast cancer (TNBC) progression. Although immune checkpoint inhibitors (ICIs) shed new light on reversing AIR, the treatment effect and predictive markers of immunotherapy remain controversial. The present study focused on epigenetic regulation for TNBC AIR and explored whether this could be clinically targeted. Methods: Through screening an epigenetic gene set in TNBC patients from The Cancer Genome Atlas (TCGA), ARID1A was pinpointed as most significantly correlated with AIR. Humanized immune system (HIS) mice were adopted for TNBC transplantation, identifying CD8+ T cells as most significantly correlated with TNBC ARID1A. To probe the mechanism underlying TNBC ARID1A deficiency-induced CD8+ T cell malfunction and AIR, RNA-seq of both TNBC patients and TNBC cell lines were analyzed and the candidate mediator gene, PD-L1, was identified and verified through western blot, qPCR, IHC, dual luciferase reporter assay and cell co-culture. Chromatin immunoprecipitation and ATAC-seq further demonstrated direct binding of ARID1A to NPM1 promoter to regulate PD-L1 expression. Finally, HIS mice were treated with ICI and the clinical trial CTR20191353 was retrospectively analyzed. Results: Among a series of epigenetic modulators, we first observed that ARID1A, a core subunit of the chromatin remodeling complex SWI/SNF, demonstrated highest correlation with AIR in TNBC patients. This was verified in HIS TNBC mice and a patient cohort from Fudan University Shanghai Cancer Center by higher malignancy observed in ARID1A-deficient TNBC. Both bulk and single-cell RNA-seq in TNBC patients uncovered an immunosuppressive microenvironment induced by TNBC ARID1A deficiency, and CD8+ T cells was identified as the immune cell type most significantly correlated with TNBC ARID1A. CD8+ T cell malfunction and AIR in ARID1A-deficient TNBC was induced by upregulated PD-L1, but ARID1A did not directly regulate PD-L1 expression. We found that ARID1A bound to the NPM1 promoter and that ARID1A deficiency increased NPM1 chromatin accessibility as well as gene expression, further activating PD-L1 transcription. In HIS mice, ICI demonstrated the potential to reverse TNBC ARID1A deficiency-induced AIR manifested by reducing tumor malignancy and activating antitumor immunity. In CTR20191353, a phase 1b clinical trial of pucotenlimab combined with chemotherapy for TNBC, patients with ARID1A deficiency demonstrated significantly better prognosis and the longest progression-free survival was found in ARID1A-low/PD-L1-high group. Conclusions: In AIR epigenetics, TNBC ARID1A deficiency induced AIR via the ARID1A/NPM1/PD-L1 axis, leading to poor outcome. While ARID1A deficiency provided survival advantage for TNBC cells, it simultaneously left the Achilles' heel which could be targeted with ICI.

Thioacetamide-induced liver fibrosis is reduced in humanized immune system mice

Abstract Fibrosis is defined as a consequence of the abnormal wound-healing response lading to excessive deposition of extracellular matrix components. Chronic liver diseases accompanied with liver fibrosis have caused increased morbidity and mortality worldwide. Carbon tetrachloride (CCl 4) and thioacetamide (TAA) are the well-known toxins used to induce liver fibrosis in murine. Compared to CCl 4, TAA displays a longer latency between exposures to the drug and less safety concerns with operators. In addition, the translation of murine experimental data to human events often fails due to differences in the immune system of both species, indicating that humanized mice may be a better choice to model human diseases. The effect of TAA in humanized mice is still unknown. In our study, liver fibrosis in wild type mice was induced by escalating doses of TAA. Results showed that liver fibrosis evaluated by Sirius red staining was significantly induced (Metavir score, F2). In addition, serum levels of AST, ALT and ALP were significantly increased after TAA injection. Humanized mice were generated by injection of human hematopoietic stem cells (hHSC) into NOD.Cg-PrkdcscidIl2rgtm1Wjl/YckNarl (Advanced Severe ImmunoDeficiency (ASID)) mice, termed as hHSC-ASID. The escalating doses of TAA were introduced into hHSC-ASID and ASID mice. Although the serum levels of AST, ALT and ALP were increased in both hHSC-ASID and ASID mice following TAA injection, the degree of liver fibrosis was reduced in hHSC-ASID mice than in ASID mice (Metavir score, F1 vs. F2). These results indicated that human immune cells reduced TAA-induced liver fibrosis. It is worthwhile to assess which immune cell(s) participates in this process.

Human CD4 cytotoxic T lymphocytes mediate potent tumor control in humanized immune system mice

Efficacy of immune checkpoint inhibitors in cancers can be limited by CD8 T cell dysfunction or HLA-I down-regulation. Tumor control mechanisms independent of CD8/HLA-I axis would overcome these limitations. Here, we report potent CD4 T cell-mediated tumor regression and memory responses in humanized immune system (HIS) mice implanted with HT-29 colorectal tumors. The regressing tumors showed increased CD4 cytotoxic T lymphocyte (CTL) infiltration and enhanced tumor HLA-II expression compared to progressing tumors. The intratumoral CD4 T cell subset associated with tumor regression expressed multiple cytotoxic markers and exhibited clonal expansion. Notably, tumor control was abrogated by depletion of CD4 but not CD8 T cells. CD4 T cells derived from tumor-regressing mice exhibited HLA-II-dependent and tumor-specific killing ex vivo. Taken together, our study demonstrates a critical role of human CD4 CTLs in mediating tumor clearance independent of CD8 T cells and provides a platform to study human anti-tumor immunity in vivo.

Spontaneous tumor regression mediated by human T cells in a humanized immune system mouse model

Immunodeficient mice reconstituted with a human immune system (HIS mice) give rise to human T cells, which make them an attractive system to study human immune responses to tumors. However, such HIS mice typically exhibit sub-optimal responses to immune challenges as well as fail to develop antigen-specific B or T cell memory. Here we report HIS mice mediate spontaneous regression of human B cell lymphoma Raji. Tumor regression was dependent on CD4+ and CD8+ T cell responses and resulted in T cell memory. The T cell memory elicited was mainly Raji-specific, however some level of cross-protection was also elicited to a related B cell lymphoma cell line Ramos. Single-cell RNAseq analysis indicated activation of CD8+ T cells in regressing Raji tumors as well as clonal expansion of specific T cell receptors (TCRs). Cloning of TCRs from Raji-infiltrating T cells into a Jurkat reporter cell line showed reactivity specific for Raji tumor cells. Overall, we report a platform for studying in vivo human T cell tumor immunity by highlighting spontaneous Raji tumor regression, clonal TCR expansion, and T cell memory in HIS mice.

Abstract 5204: Preclinical models for translational immuno-oncology research: Rare patient-derived xenografts on humanized mice

Abstract Background The preclinical evaluation of novel immune checkpoint modulators is dependent on models with functional human immune cells. In previous experiments, we have demonstrated, that we can use either peripheral blood mononuclear cells (PBMC), subset of immune cells like NK cells or hematopoietic stem cells (HSC) to establish a humanized immune system on highly immunodeficient 1st and 2nd generation NOG mice with functional T-, B-, and NK cells, as well as monocytes and dendritic cells. Furthermore, we determined PD-L1 expression as a predictive marker and target for immunotherapy on different patient-derived xenografts (PDX). By co-transplantation of rare PDX, like leukemia or Nuclear-protein-in-testis (NUT) carcinoma, we successfully generated a fully human tumor-immune-cell model in mice. Finally, we evaluated the functionality of the model by the treatment with checkpoint inhibitors like Ipilimumab (Ipi), Nivolumab (Nivo) or Pembrolizumab (Pembro). In parallel, we investigated the functionality of the human immune cells and evaluated concepts for combination therapies i.e. with chemotherapy or radiation. Methods HSC-humanized mice were generated by i.v. HSC transplantation and engraftment of immune cells was monitored by FACS analysis. For PBMC-humanized mice, immune cells were implanted i.v.. PDX models from different entities (leukemia or NUT carcinoma) were transplanted on HSC-humanized (HIS) mice and treated with Ipi, Nivo and Pembro alone or in combination with radiation. Blood and tumor samples were analysed by FACS for immune cell infiltration and activation. Results The transplanted HSC showed engraftment in mice with proliferation and differentiation. 14 weeks after HSC inoculation up to 20% of the human immune cells in the blood were T-cells, characterized by a high PD-1 expression. We have transplanted PDX from different tumor entities on HSC-humanized mice. Most of the investigated PDX (>70%) successfully engrafted on humanized mice and showed no significant difference in tumor growth compared to growth on non-humanized mice. However, for some PDX we observed a delayed tumor growth or a complete rejection. Engraftment delay seems to correlate with the PD-L1 expression of PDX (the higher PD-L1, then the higher growth delay). Furthermore, our results demonstrate the functionality of the engrafted human immune cells against some PDX. Treatment with Ipi, Nivo or Pembro led to a minor tumor growth delay. Response to checkpoint inhibitors showed a correlation to innate immune response and PD-L1 expression of PDX and could further be increased by combination with radiotherapy. Conclusions Our humanized immune-PDX models enable appropriate preclinical translational research on tumor immune biology and the evaluation of new therapies and combinations, as well as the identification and validation of biomarkers for immune therapy, especially in rare PDX models. Citation Format: Maria Stecklum, Annika Wulf-Goldenberg, Bernadette Brzezicha, Wolfgang Walther, Jens Hoffmann. Preclinical models for translational immuno-oncology research: Rare patient-derived xenografts on humanized mice. [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2023; Part 1 (Regular and Invited Abstracts); 2023 Apr 14-19; Orlando, FL. Philadelphia (PA): AACR; Cancer Res 2023;83(7_Suppl):Abstract nr 5204.

The PRMT5 inhibitor EPZ015666 is effective against HTLV-1-transformed T-cell lines in vitro and in vivo.

Human T-cell leukemia virus type 1 (HTLV-1) is the infectious cause of adult T-cell leukemia/lymphoma (ATL), an extremely aggressive and fatal malignancy of CD4+ T-cells. Due to the chemotherapy-resistance of ATL and the absence of long-term therapy regimens currently available for ATL patients, there is an urgent need to characterize novel therapeutic targets against this disease. Protein arginine methyltransferase 5 (PRMT5) is a type II PRMT enzyme that is directly involved in the pathogenesis of multiple different lymphomas through the transcriptional regulation of relevant oncogenes. Recently, our group identified that PRMT5 is overexpressed in HTLV-1-transformed T-cell lines, during the HTLV-1-mediated T-cell immortalization process, and in ATL patient samples. The objective of this study was to determine the importance of PRMT5 on HTLV-1 infected cell viability, T-cell transformation, and ultimately disease induction. Inhibition of PRMT5 enzymatic activity with a commercially available small molecule inhibitor (EPZ015666) resulted in selective in vitro toxicity of actively proliferating and transformed T-cells. EPZ015666-treatment resulted in a dose-dependent increase in apoptosis in HTLV-1-transformed and ATL-derived cell lines compared to uninfected Jurkat T-cells. Using a co-culture model of infection and immortalization, we found that EPZ015666 is capable of blocking HTLV-1-mediated T-cell immortalization in vitro, indicating that PRMT5 enzymatic activity is essential for the HTLV-1 T-cell transformation process. Administration of EPZ015666 in both NSG xenograft and HTLV-1-infected humanized immune system (HIS) mice significantly improved survival outcomes. The cumulative findings of this study demonstrate that the epigenetic regulator PRMT5 is critical for the survival, transformation, and pathogenesis of HTLV-1, illustrating the value of this cellular enzyme as a potential therapeutic target for the treatment of ATL.

Pulmonary human immune responses in a humanized immune mouse model during influenza virus infection

<p>Human immune system is complex and differs significantly from that of model animals. To study the human immune system, particularly the local mucosal immune cells responding to infectious diseases, the humanized mouse model is a powerful tool. In this study, we established a humanized immune system (HIS) mouse model by transplanting CD34<sup>+</sup> hematopoietic stem cells from human umbilical cord blood into hIL7/hIL15 NDG mice. We successfully developed conventional human immune cells, including T cells, B cells, NK cells, monocytes, DCs and resident innate lymphoid cells (ILCs) in HIS mice. Following influenza A virus (IAV) infection, human pulmonary immune cells were activated and accumulated in the lungs. Single-cell sequencing data revealed that these immune cells functioned effectively in defending against viral infection by expressing cytotoxic cytokines and upregulating interferon-induced genes (ISGs). Furthermore, we identified human-specific genes that participated in regulating mucosal immune responses. Overall, hIL7/hIL15 HIS mice provide a useful model for studying human local immune responses against IAV in vivo.</p>

NEO-TRA1: A CD25-Targeted De Novo non-Alpha Agonist of the IL-2 Receptor Selectively Expands Regulatory T Cells

Introduction: Regulatory T cells (Tregs) are crucial for maintaining immune tolerance and their dysfunction contributes to inflammatory and autoimmune conditions, such as graft versus host disease (GVHD). IL-2 is a pleiotropic cytokine that activates both immunosuppressive Tregs and inflammatory cells, including NK cells, cytotoxic T cells, and helper T cells. Although low dose IL-2 therapy effectively expands Tregs, this intervention is limited by coincident stimulation of conventional T cells and natural killer cells. Investigational therapeutics derived from directed mutagenesis of native IL-2 sequences have resulted in some improvements in Treg selectivity. To optimize the magnitude and selectivity of Treg expansion, we utilized de novo protein design technology to fine-tune the individual receptor interfaces of IL-2 mimetic proteins targeted to Tregs with CD25 antibodies. We found decoupling receptor agonism and targeting is an effective means of improving Treg stimulation and corresponding therapeutic candidates elicit robust expansion of Treg populations in vivo without detectable stimulation of inflammatory immune cells. Methods: We designed a series of de novo IL-2Ra independent agonists of the IL-2 receptor that demonstrate reduced binding affinity to CD122 and CD132, the beta and gamma chains of the IL-2 receptor complex, by up to 5 logs when compared to IL-2. These non-alpha IL-2 mimetic variants were fused to a humanized anti-CD25 mAb that lacks effector function for cis-targeting to Tregs. Candidate molecules were screened on primary human T cells to assess pSTAT5 signaling. Treg-specific molecules were administered to humanized NSG mice weekly (four times) and peripheral blood was collected for immune cell profiling via flow cytometry. Results: Screening of TRA candidates in primary human T cells identified several highly selective Treg agonists, including NEO-TRA1 (Fig1). At all concentrations, CD8+ and CD4+ non-Tregs showed low or negligible levels of pSTAT5 signaling upon treatment with NEO-TRA1. Nevertheless, CD4+CD25highCD127low Tregs show increasing pSTAT5 signaling at a wide range of concentrations starting at 20pM, and demonstrate preferential signaling in Tregs by NEO-TRA1. To establish the ability of our TRA to expand Treg in vivo, NSG mice engrafted with human hematopoietic stem cells to create a humanized immune system received weekly injections of NEO-TRA1, vehicle control, or a previously described Treg selective IL-2 mutein (IL-2v-Fc). Characterization of Day 13 CD4+CD25+Foxp3+ Treg percentages in peripheral blood mononuclear cells show that the Treg population expanded to ~30% of total CD4+ cells in mice receiving NEO-TRA1, while Treg percentages reached ~22% in mice receiving IL-2v-Fc (Fig2). Despite a slight decrease at Day 20, the Treg percentages remained higher in NEO-TRA1-treated cohorts than in control groups throughout the study. Conclusions: NEO-TRA1 exhibits potent expansion of Treg populations within primary human samples and in humanized mouse models. The observed profile of STAT5 phosphorylation demonstrates selective activation of Tregs over other lymphocyte populations. NEO-TRA1 is the first Treg agonist based on de novo protein design. NEO-TRA1 is both specific and potent and has high therapeutic potential for the treatment of GVHD and other autoimmune or inflammation diseases. Figure 1View largeDownload PPTFigure 1View largeDownload PPT Close modal

The development and improvement of immunodeficient mice and humanized immune system mouse models.

Animal models play an indispensable role in the study of human diseases. However, animal models of different diseases do not fully mimic the complex internal environment of humans. Immunodeficient mice are deficient in certain genes and do not express these or show reduced expression in some of their cells, facilitating the establishment of humanized mice and simulation of the human environment in vivo. Here, we summarize the developments in immunodeficient mice, from the initial nude mice lacking T lymphocytes to NOD/SCID rgnull mice lacking T, B, and NK cell populations. We describe existing humanized immune system mouse models based on immunodeficient mice in which human cells or tissues have been transplanted to establish a human immune system, including humanized-peripheral blood mononuclear cells (Hu-PBMCs), humanized hematopoietic stem cells (Hu-HSCs), and humanized bone marrow, liver, thymus (Hu-BLT) mouse models. The different methods for their development involve varying levels of complexity and humanization. Humanized mice are widely used in the study of various diseases to provide a transitional stage for clinical research. However, several challenges persist, including improving the efficiency of reconstructing the human B cell immune response, extending lifespan, improving the survival rate of mice to extend the observation period, and improving the development of standardized commercialized models and as well as their use. Overall, there are many opportunities and challenges in the development of humanized immune system mouse models which can provide novel strategies for understanding the mechanisms and treatments of human disease.