Single-cell RNA sequencing combined with single-cell proteomics identifies the metabolic adaptation of islet cell subpopulations to high-fat diet in mice

Fu, Qi; Jiang, Hemin; Q, Yu; Lv, Hui; Dai, Hao; Zhou, Yuncai; Chen, Yang; He, Yunqiang; Gao, Rui; Zheng, Shuai; Liang, Yucheng; Li, Siqi; Xu, Xinyu; Xu, Kuanfeng; Yang, Tao

doi:10.1007/s00125-022-05849-5

Cited by 9 publications

(3 citation statements)

References 43 publications

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“…Minimally biased interrogation of proteins and protein networks selectively present in β cells and  cell states builds on past efforts to map the  cell proteome. Previously established FACS purifying mouse  cell populations based on insulin immunoreactivity yielded 6955 proteins across 36 islet samples with various diets and islet cell types (20), and led to the identification of a subpopulation of β cells with low CD81 expression which had enrichment for factors in spliceosome and RNA processing pathways, but reduced oxidative phosphorylation factors, similar to our Ins2(GFP) HIGH cells (20). Two β cell subpopulations identified in a study on human β cell scRNAseq data had low INS expression, and while one high UPR marker expression, the other had enrichment in pathways related to oxidative stress (8).…”

Section: Discussionmentioning

confidence: 99%

Signal transduction pathways controllingIns2gene activity and β cell state transitions

Chu,

Sabbineni,

Cen

et al. 2024

Preprint

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Pancreatic β cells exist in low and high insulin gene activity states that are dynamic on a scale of hours to days. Cells with higherIns2gene activity have a ‘mature’ β cell transcriptomic profile but are more fragile. Information remains unknown on the spatial relationship between these β cell states, their proteomic signatures, and the signaling mechanisms underlying state transitions. Here, we used live 3D imaging, mass spectrometry proteomics, and 48 targeted perturbations of β cell signaling pathways to comprehensively investigateIns2(GFP)HIGHandIns2(GFP)LOWβ cell states. We found that the twoIns2gene activity states exist in intact isolated islets, and cells in the same state were more likely to be nearer to each other. We report the proteomes of pure β cells to a depth of 5555 proteins and show that β cells with highIns2gene activity had increased transcriptional and mRNA processing factors, as well as increased translation rate. We identified activators of cAMP signaling (GLP1, IBMX) as powerful drivers of both GFP expression and transitions fromIns2(GFP)LOWto theIns2(GFP)HIGHstates. Okadaic acid and cyclosporine A had the opposite effects. This study provides new insight into the proteomic profiles and regulation of β cell states.Article highlightsWhy did we undertake this study?We sought to define the proteomic signatures of β cell maturity states and understand the mechanisms regulatingIns2gene activity and state transitions.What are the specific questions we wanted to answer?What are the islet spatial distribution and proteomic profiles of β cell maturity states?What are the molecular mechanisms controllingIns2gene activity and state transitions?What did we find?In intact islets, β cells in the highIns2state are more likely to be close to each other.IRF3, CLIP1, PAPSS2, YWHAZ, and AIFM1 are the most β cell-specific proteins in mouse islets.HighIns2activity coincides with upregulation of proteins involved in transcriptional regulation and processing.Agonists and drugs that augment cAMP signaling increaseIns2gene activity while calcineurin inhibitors cyclosporine A and okadaic acid reducedIns2gene activity.What are the implications of our findings?Cells with highIns2gene activity have evidence of increased transcriptional capacity. cAMP and calcineurin signaling regulateIns2gene activity and cell state transitions.

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Section: Discussionmentioning

confidence: 99%

Signal transduction pathways controllingIns2gene activity and β cell state transitions

Chu,

Sabbineni,

Cen

et al. 2024

Preprint

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“…The cells were suspended in KRHB buffer with 2.8 mM glucose. Normal β cells were obtained through negative selection with magnetic activated cell sorting (MACS) using the α cell marker ACE2 53 (anti-ACE2-Biotin (Novus, cat. #NBP1-76614B, 1:10)), and the δ-cell marker CD24 54 (anti-CD24-Biotin (Miltenyi Biotec, clone M1/ 69, cat.…”

Section: Cell Culturementioning

confidence: 99%

Trimethylamine N-oxide impairs β-cell function and glucose tolerance

Kong,

Zhao,

Jiang

et al. 2024

Nat Commun

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Abstractβ-Cell dysfunction and β-cell loss are hallmarks of type 2 diabetes (T2D). Here, we found that trimethylamine N-oxide (TMAO) at a similar concentration to that found in diabetes could directly decrease glucose-stimulated insulin secretion (GSIS) in MIN6 cells and primary islets from mice or humans. Elevation of TMAO levels impairs GSIS, β-cell proportion, and glucose tolerance in male C57BL/6 J mice. TMAO inhibits calcium transients through NLRP3 inflammasome-related cytokines and induced Serca2 loss, and a Serca2 agonist reversed the effect of TMAO on β-cell function in vitro and in vivo. Additionally, long-term TMAO exposure promotes β-cell ER stress, dedifferentiation, and apoptosis and inhibits β-cell transcriptional identity. Inhibition of TMAO production improves β-cell GSIS, β-cell proportion, and glucose tolerance in both male db/db and choline diet-fed mice. These observations identify a role for TMAO in β-cell dysfunction and maintenance, and inhibition of TMAO could be an approach for the treatment of T2D.

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“…The ACE2, CD81, and GLUT2 markers screened in the study enable the differentiation of α, β, and δ cell subpopulations based on their maturity and functional status. Targeting these markers may alter islet subpopulation distribution, thereby enhancing islet function [ 121 ]. Multiple myeloma, which is prone to drug-resistant relapse, is an adult hematologic malignancy.…”

Section: Integrated Analysis Of Scrna-seq and Multi-omicsmentioning

confidence: 99%

The Advancement and Application of the Single-Cell Transcriptome in Biological and Medical Research

Huang,

Xu,

Feng

et al. 2024

Biology

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Single-cell RNA sequencing technology (scRNA-seq) has been steadily developing since its inception in 2009. Unlike bulk RNA-seq, scRNA-seq identifies the heterogeneity of tissue cells and reveals gene expression changes in individual cells at the microscopic level. Here, we review the development of scRNA-seq, which has gone through iterations of reverse transcription, in vitro transcription, smart-seq, drop-seq, 10 × Genomics, and spatial single-cell transcriptome technologies. The technology of 10 × Genomics has been widely applied in medicine and biology, producing rich research results. Furthermore, this review presents a summary of the analytical process for single-cell transcriptome data and its integration with other omics analyses, including genomes, epigenomes, proteomes, and metabolomics. The single-cell transcriptome has a wide range of applications in biology and medicine. This review analyzes the applications of scRNA-seq in cancer, stem cell research, developmental biology, microbiology, and other fields. In essence, scRNA-seq provides a means of elucidating gene expression patterns in single cells, thereby offering a valuable tool for scientific research. Nevertheless, the current single-cell transcriptome technology is still imperfect, and this review identifies its shortcomings and anticipates future developments. The objective of this review is to facilitate a deeper comprehension of scRNA-seq technology and its applications in biological and medical research, as well as to identify avenues for its future development in alignment with practical needs.

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Single-cell RNA sequencing combined with single-cell proteomics identifies the metabolic adaptation of islet cell subpopulations to high-fat diet in mice

Cited by 9 publications

References 43 publications

Signal transduction pathways controllingIns2gene activity and β cell state transitions

Signal transduction pathways controllingIns2gene activity and β cell state transitions

Trimethylamine N-oxide impairs β-cell function and glucose tolerance

The Advancement and Application of the Single-Cell Transcriptome in Biological and Medical Research

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