Human immunology studies using organ donors: Impact of clinical variations on immune parameters in tissues and circulation

Carpenter, Dustin; Granot, Tomer; Matsuoka, Naoki; Senda, Takashi; Kumar, Brahma V.; Thome, Joseph J.C.; Gordon, Claire L.; Miron, Michelle; Weiner, Joshua; Connors, Thomas J.; Lerner, Harvey; Friedman, Amy L.; Kato, Tomoaki; Griesemer, Adam; Farber, Donna L.

doi:10.1111/ajt.14434

Cited by 61 publications

(86 citation statements)

References 45 publications

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“…We note that the purpose of our study is to demonstrate how omics data can be used to calibrate a QSP model, rather than to qualify a model for application in drug development. Figure 3 shows the constraints on state variables in the minimal CIC model based on data from "Immune Landscape of Cancer" (Figure 1a,b), high-throughput flow cytometry of human donor tissues, [13][14][15] T-cell repertoire sequencing, 16 and the established literature of basic cellular composition of the immune system. State variables describing cell populations in most QSP models in IOincluding the minimal model presented here-are expressed as absolute cell numbers rather than relative amounts.…”

Section: Minimal Model Calibration Using Omics Datamentioning

confidence: 99%

“…In a series of recent studies, Farber's group applied high-throughput flow cytometry to organ donor tissues to quantitatively describe the state of the immune system in healthy individuals. [13][14][15] These unique data provide insight into relative distributions of multiple T-cell types and dendritic cells among different tissues, including lymph nodes. Thome et al 13 studied tissues from 56 donors and determined the distribution of CD4 and CD8 T-cells in peripheral blood, spleen, inguinal lymph node (draining the peripheral skin and muscle), lung-draining lymph node, lungs, mesenteric lymph node (draining the intestines), small intestine (jejunum and ileum), and colon.…”

Section: The Omics Data Coverage Of Cancer Immunity Cyclementioning

confidence: 99%

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Integration of Omics Data Sources to Inform Mechanistic Modeling of Immune‐Oncology Therapies: A Tutorial for Clinical Pharmacologists

Lazarou¹,

Chelliah²,

Small³

et al. 2020

Clin Pharma and Therapeutics

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Application of contemporary molecular biology techniques to clinical samples in oncology resulted in the accumulation of unprecedented experimental data. These “omics” data are mined for discovery of therapeutic target combinations and diagnostic biomarkers. It is less appreciated that omics resources could also revolutionize development of the mechanistic models informing clinical pharmacology quantitative decisions about dose amount, timing, and sequence. We discuss the integration of omics data to inform mechanistic models supporting drug development in immuno‐oncology. To illustrate our arguments, we present a minimal clinical model of the Cancer Immunity Cycle (CIC), calibrated for non‐small cell lung carcinoma using tumor microenvironment composition inferred from transcriptomics of clinical samples. We review omics data resources, which can be integrated to parameterize mechanistic models of the CIC. We propose that virtual trial simulations with clinical Quantitative Systems Pharmacology platforms informed by omics data will be making increasing impact in the development of cancer immunotherapies.

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Section: Minimal Model Calibration Using Omics Datamentioning

confidence: 99%

Section: The Omics Data Coverage Of Cancer Immunity Cyclementioning

confidence: 99%

Integration of Omics Data Sources to Inform Mechanistic Modeling of Immune‐Oncology Therapies: A Tutorial for Clinical Pharmacologists

Lazarou¹,

Chelliah²,

Small³

et al. 2020

Clin Pharma and Therapeutics

View full text Add to dashboard Cite

show abstract

“…These findings suggest that localization of T cells in tissues likely involves structural changes in the cell that facilitate interactions with tissue matrix. 9 We compared the single-cell distribution of average expression of tissue signature genes in the blood and three tissues ( Fig. 3d).…”

Section: A Universal Gene Signature Distinguishes Tissue T Cells Frommentioning

confidence: 99%

“…In humans, most of our knowledge of T cell activation and function derives from the sampling of peripheral blood. Recent studies in human tissues have revealed that the majority of human T cells are localized in lymphoid mucosal and barrier tissues 8 and that T cell subset composition is a function of the specific tissue site 9,10 . Human TRM cells can be defined based on their phenotypic homology to mouse TRM and are distinguished from circulating T cells in blood and tissues by a core transcriptional and protein signature [10][11][12][13] .…”

Section: Introductionmentioning

confidence: 99%

“…This approach has been applied to analyze human T cells in diseased tissues 25,26 and in response to immunotherapies in cancer 27 ; however, the baseline functional profiles of human T cells in healthy blood and tissues have not been defined. We have established a tissue resource where we obtain multiple lymphoid, mucosal, and other peripheral tissue sites from human organ donors [9][10][11]13,28,29 , enabling study of T cells across different anatomical spaces. Here, we used scRNA-seq of over 50,000 resting and activated T cells from lung (LG), lymph nodes (LN), bone marrow (BM) and blood, along with innovative computational analysis to define cellular states of homeostasis and activation of human blood and tissue-derived T cells.…”

Section: Introductionmentioning

confidence: 99%

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A single-cell reference map for human blood and tissue T cell activation reveals functional states in health and disease

Szabo

Levitin

Miron

et al. 2019

Preprint

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Human T cells coordinate adaptive immunity by localization in diverse tissue sites, though blood T cells are the most readily studied. Here, we used single-cell RNA-seq to define the functional responses of T cells isolated from human lungs, lymph nodes, bone marrow, and blood to TCRstimulation. We reveal how human T cells in tissues relate to those in blood, and define activation states for CD4 + and CD8 + T cells across all sites, including an interferon-response state for CD4 + T cells and distinct effector states for CD8 + T cells. We further show how profiles of individual tumorassociated T cells can be projected onto this healthy reference map, revealing their functional state.6

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Use of human splenocytes in an innovative humanised mouse model for prediction of immunotherapy‐induced cytokine release syndrome

et al. 2020

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Objectives Humanised mice have emerged as valuable models for pre‐clinical testing of the safety and efficacy of immunotherapies. Given the variety of models available, selection of the most appropriate humanised mouse model is critical in study design. Here, we aimed to develop a model for predicting cytokine release syndrome (CRS) while minimising graft‐ versus ‐host disease (GvHD). Methods To overcome donor‐induced variation, we directly compared the in vitro and in vivo immune phenotype of immunodeficient NSG mice reconstituted with human bone marrow (BM) CD34 + haematopoietic stem cells (HSCs), peripheral blood mononuclear cells (PBMCs) or spleen mononuclear cells (SPMCs) from the same human donors. SPMC engraftment in NSG‐dKO mice, which lack MHC class I and II, was also evaluated as a strategy to limit GvHD. Another group of mice was engrafted with umbilical cord blood (UCB) CD34 + HSCs. Induction of CRS in vivo was investigated upon administration of the anti‐CD3 monoclonal antibody OKT3. Results PBMC‐ and SPMC‐reconstituted NSG mice showed short‐term survival, with engrafted human T cells exhibiting mostly an effector memory phenotype. Survival in SPMC‐reconstituted NSG‐dKO mice was significantly longer. Conversely, both BM and UCB‐HSC models showed longer survival, without demonstrable GvHD and a more naïve T‐cell phenotype. PBMC‐ and SPMC‐reconstituted mice, but not BM‐HSC or UCB‐HSC mice, experienced severe clinical signs of CRS upon administration of OKT3. Conclusion PBMC‐ and SPMC‐reconstituted NSG mice better predict OKT3‐mediated CRS. The SPMC model allows generation of large experimental groups, and the use of NSG‐dKO mice mitigates the limitation of early GvHD.

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Human immunology studies using organ donors: Impact of clinical variations on immune parameters in tissues and circulation

Cited by 61 publications

References 45 publications

Integration of Omics Data Sources to Inform Mechanistic Modeling of Immune‐Oncology Therapies: A Tutorial for Clinical Pharmacologists

Integration of Omics Data Sources to Inform Mechanistic Modeling of Immune‐Oncology Therapies: A Tutorial for Clinical Pharmacologists

A single-cell reference map for human blood and tissue T cell activation reveals functional states in health and disease

Use of human splenocytes in an innovative humanised mouse model for prediction of immunotherapy‐induced cytokine release syndrome

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