Revolutionizing Immunological Disease Understanding Through Single Cell Multi-Omics Technologies

Editorial

30 May 2025

Editorial: Revolutionizing immunological disease understanding through single cell multi-omics technologies

Ying Zhu

Veronica G. Anania

Jennie R. Lill

and

Zora Modrusan

1,411 views

0 citations

Editors

Impact

Original Research

13 May 2025

Investigating the molecular mechanisms associated with ulcerative colitis through the application of single-cell combined spatial transcriptome sequencing

Hua Huang

, 5 more and

Lijiang Ji

2,463 views

0 citations

Original Research

14 January 2025

Upregulation of interferon-γ response genes in monocytes and T cells identified by single-cell transcriptomics in patients with anti-citrullinated peptide antibody-positive early rheumatoid arthritis

Bong-Ki Hong

, 8 more and

Ho-Youn Kim

2,676 views

1 citations

Original Research

13 January 2025

Single-cell RNA-seq reveals immune cell heterogeneity and increased Th17 cells in human fibrotic skin diseases

Cheng-Cheng Deng

, 7 more and

Bin Yang

4,810 views

3 citations

Original Research

19 July 2024

Spatial and phenotypic heterogeneity of resident and monocyte-derived macrophages during inflammatory exacerbations leading to pulmonary fibrosis

Philip J. Moos

, 5 more and

Alessandro Venosa

6,607 views

3 citations

Review

09 January 2025

Advancing precision cancer immunotherapy drug development, administration, and response prediction with AI-enabled Raman spectroscopy

Jay Chadokiya

, 5 more and

Amanda Kirane

3,896 views

1 citations

Original Research

25 June 2024

Using adjusted local assortativity with Molecular Pixelation unveils colocalization of membrane proteins with immunological significance

Jan Rhomberg-Kauert

, 6 more and

Alvaro Martinez Barrio

2,297 views

0 citations

Original Research

30 October 2024

A cost-effective protocol for single-cell RNA sequencing of human skin

Saba Khoshbakht

, 9 more and

Seçil Vural

2,029 views

0 citations

Original Research

20 November 2023

Identification of drug candidates targeting monocyte reprogramming in people living with HIV

Rainer Knoll

, 20 more and

Anna C. Aschenbrenner

Introduction: People living with HIV (PLHIV) are characterized by functional reprogramming of innate immune cells even after long-term antiretroviral therapy (ART). In order to assess technical feasibility of omics technologies for application to larger cohorts, we compared multiple omics data layers.

Methods: Bulk and single-cell transcriptomics, flow cytometry, proteomics, chromatin landscape analysis by ATAC-seq as well as ex vivo drug stimulation were performed in a small number of blood samples derived from PLHIV and healthy controls from the 200-HIV cohort study.

Results: Single-cell RNA-seq analysis revealed that most immune cells in peripheral blood of PLHIV are altered in their transcriptomes and that a specific functional monocyte state previously described in acute HIV infection is still existing in PLHIV while other monocyte cell states are only occurring acute infection. Further, a reverse transcriptome approach on a rather small number of PLHIV was sufficient to identify drug candidates for reversing the transcriptional phenotype of monocytes in PLHIV.

Discussion: These scientific findings and technological advancements for clinical application of single-cell transcriptomics form the basis for the larger 2000-HIV multicenter cohort study on PLHIV, for which a combination of bulk and single-cell transcriptomics will be included as the leading technology to determine disease endotypes in PLHIV and to predict disease trajectories and outcomes.

24,327 views

9 citations

Original Research

28 November 2023

The Simple prEservatioN of Single cElls method for cryopreservation enables the generation of single-cell immune profiles from whole blood

Sarthak Satpathy

, 8 more and

Manoj K. Bhasin

4,689 views

8 citations

Original Research

16 October 2023

Cell-type-specific molecular characterization of cells from circulation and kidney in IgA nephropathy with nephrotic syndrome

Qilin Chen

, 18 more and

Qiu Li

Nephrotic syndrome (NS) is a relatively rare and serious presentation of IgA nephropathy (IgAN) (NS-IgAN). Previous research has suggested that the pathogenesis of NS-IgAN may involve circulating immune imbalance and kidney injury; however, this has yet to be fully elucidated. To investigate the cellular and molecular status of NS-IgAN, we performed single-cell RNA sequencing (scRNA-seq) of peripheral blood mononuclear cells (PBMCs) and kidney cells from pediatric patients diagnosed with NS-IgAN by renal biopsy. Consistently, the proportion of intermediate monocytes (IMs) in NS-IgAN patients was higher than in healthy controls. Furthermore, flow cytometry confirmed that IMs were significantly increased in pediatric patients with NS. The characteristic expression of VSIG4 and MHC class II molecules and an increase in oxidative phosphorylation may be important features of IMs in NS-IgAN. Notably, we found that the expression level of CCR2 was significantly increased in the CMs, IMs, and NCMs of patients with NS-IgAN. This may be related to kidney injury. Regulatory T cells (Tregs) are classified into two subsets of cells: Treg1 (CCR7^high, TCF7^high, and HLA-DR^low) and Treg2 (CCR7^low, TCF7^low, and HLA-DR^high). We found that the levels of Treg2 cells expressed significant levels of CCR4 and GATA3, which may be related to the recovery of kidney injury. The state of NS in patients was closely related to podocyte injury. The expression levels of CCL2, PRSS23, and genes related to epithelial-mesenchymal transition were significantly increased in podocytes from NS-IgAN patients. These represent key features of podocyte injury. Our analysis suggests that PTGDS is significantly downregulated following injury and may represent a new marker for podocytes. In this study, we systematically analyzed molecular events in the circulatory system and kidney tissue of pediatric patients with NS-IgAN, which provides new insights for targeted therapy in the future.