Single-cell transcriptomics of blood reveals a natural killer cell subset depletion in tuberculosis

Cai, Yi; Dai, Youchao; Wang, Yejun; Yang, Qianqing; Guo, Jiubiao; Wei, Cailing; Chen, Weixin; Huang, Huanping; Zhu, Jialou; Zhang, Chi; Zheng, Weidong; Wen, Zhihua; Liu, Haiying; Zhang, Mingxia; Xing, Shaojun; Jin, Qi; Feng, Carl G.; Chen, Xinchun

doi:10.1016/j.ebiom.2020.102686

Cited by 94 publications

(102 citation statements)

References 78 publications

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“…Conventional enumeration of peripheral blood mononuclear cells (PBMCs) and their subsets have failed to identify determinants of outcome among these cells for this complex patient population. Single cell transcriptomic approaches continue to modify and expand our understanding of the function and classification of PBMC subsets (2,3). The degree to which these sophisticated approaches will lead to clinically actionable information remains to be established (4).…”

Section: Introductionmentioning

confidence: 99%

The inflammasome of circulatory collapse: single cell analysis of survival on extracorporeal life support

Kort

Weiland

Grins

et al. 2019

Preprint

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As both sentinels and effectors of disease response, peripheral blood mononuclear cells are an accessible and attractive target for clinical application of high throughput, fluidics based single cell RNASeq (scRNASeq). However, new analytic tools required by unique characteristics of scRNASeq data lack validation in acutely ill patients. We report scRNASeq analysis of ~1,000 20 cells from each of 38 patients requiring veno-arterial extracorporeal life support (VA-ECLS)-a diverse group of critically ill patients experiencing circulatory collapse as a common endpoint to wide ranging diseases. We established an analysis pipeline capturing major biological signals from theses samples, confirmed by flow cytometry. Further, we found that these patients appeared immunologically poised at the outset of treatment as either reactive or permissive, and 25 this balance predicted their survival. Annotated code detailing the analysis is available at https://github.com/vanandelinstitute/va_ecls.

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Section: Introductionmentioning

confidence: 99%

The inflammasome of circulatory collapse: single cell analysis of survival on extracorporeal life support

Kort

Weiland

Grins

et al. 2019

Preprint

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“…Introduction: The advent of single-cell RNA sequencing (scRNA-seq) has enabled the interrogation of heterogeneous cell populations in blood without cell type isolation and has already been employed in the study of myriad immune-related diseases. 14,15,18 Recent studies employing scRNA-seq to study the role of immune cell subpopulations between healthy and ill patients, such as those for Crohn's disease 41 , Tuberculosis 40 , and COVID-19 39 , have identified cell typespecific disease relevant signatures in peripheral blood immune cells; however, these types of studies have been limited to large volume venous blood draws which can tax already ill patients, reduce the scope of studies to populations amenable to blood draws, and often require larger research teams to handle the patient logistics and sample processing costs and labor. In particular, getting repeated venous blood draws within a single day and/or multiple days at the subject's home has been a challenge for older people with frail skin and those on low dosage Acetylsalicylic acid.…”

Section: Discussionmentioning

confidence: 99%

Enabling out-of-clinic human immunity studies via single-cell profiling of capillary blood

Dobreva

Brown

Park

et al. 2020

Preprint

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An individual’s immune system is driven by both genetic and environmental factors that vary over time. To better understand the temporal and inter-individual variability of gene expression within distinct immune cell types, we developed a platform that leverages multiplexed single-cell sequencing and out-of-clinic capillary blood extraction to enable simplified, cost-effective profiling of the human immune system across people and time at single-cell resolution. Using the platform, we detect widespread differences in cell type-specific gene expression between subjects that are stable over multiple days.SummaryIncreasing evidence implicates the immune system in an overwhelming number of diseases, and distinct cell types play specific roles in their pathogenesis.1,2 Studies of peripheral blood have uncovered a wealth of associations between gene expression, environmental factors, disease risk, and therapeutic efficacy.4 For example, in rheumatoid arthritis, multiple mechanistic paths have been found that lead to disease, and gene expression of specific immune cell types can be used as a predictor of therapeutic non-response.12 Furthermore, vaccines, drugs, and chemotherapy have been shown to yield different efficacy based on time of administration, and such findings have been linked to the time-dependence of gene expression in downstream pathways.21,22,23 However, human immune studies of gene expression between individuals and across time remain limited to a few cell types or time points per subject, constraining our understanding of how networks of heterogeneous cells making up each individual’s immune system respond to adverse events and change over time.

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“…In another study, PBMCs from patients with latent tuberculosis infection (LTBI) or active tuberculosis (TB), and from healthy individuals were analyzed with scRNA-seq [34]. T cells, B cells, and myeloid cells were distinguished, and 29 subsets were clustered.…”

Section: Host Immune Responses In Infectionmentioning

confidence: 99%

The Role of Single-Cell Technology in the Study and Control of Infectious Diseases

Lin

Tay

Lu³

et al. 2020

Cells

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The advent of single-cell research in the recent decade has allowed biological studies at an unprecedented resolution and scale. In particular, single-cell analysis techniques such as Next-Generation Sequencing (NGS) and Fluorescence-Activated Cell Sorting (FACS) have helped show substantial links between cellular heterogeneity and infectious disease progression. The extensive characterization of genomic and phenotypic biomarkers, in addition to host–pathogen interactions at the single-cell level, has resulted in the discovery of previously unknown infection mechanisms as well as potential treatment options. In this article, we review the various single-cell technologies and their applications in the ongoing fight against infectious diseases, as well as discuss the potential opportunities for future development.

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Single-cell transcriptomics of blood reveals a natural killer cell subset depletion in tuberculosis

Cited by 94 publications

References 78 publications

The inflammasome of circulatory collapse: single cell analysis of survival on extracorporeal life support

The inflammasome of circulatory collapse: single cell analysis of survival on extracorporeal life support

Enabling out-of-clinic human immunity studies via single-cell profiling of capillary blood

The Role of Single-Cell Technology in the Study and Control of Infectious Diseases

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