Your search keyword '"Kalim UU"' showing total 12 results

1. A proximal enhancer regulates RORA expression during early human Th17 cell differentiation.

Author

Kalim UU, Biradar R, Junttila S, Khan MM, Tripathi S, Khan MH, Smolander J, Kanduri K, Envall T, Laiho A, Marson A, Rasool O, Elo LL, and Lahesmaa R

Subjects

Humans, Polymorphism, Single Nucleotide, Gene Expression Regulation, Nuclear Receptor Subfamily 1, Group F, Member 1 genetics, Nuclear Receptor Subfamily 1, Group F, Member 1 metabolism, Autoimmune Diseases genetics, Autoimmune Diseases immunology, Binding Sites genetics, CRISPR-Cas Systems, Cell Differentiation genetics, Cell Differentiation immunology, Enhancer Elements, Genetic genetics, Th17 Cells immunology

Abstract

Gene regulatory elements, such as enhancers, greatly influence cell identity by tuning the transcriptional activity of specific cell types. Dynamics of enhancer landscape during early human Th17 cell differentiation remains incompletely understood. Leveraging ATAC-seq-based profiling of chromatin accessibility and comprehensive analysis of key histone marks, we identified a repertoire of enhancers that potentially exert control over the fate specification of Th17 cells. We found 23 SNPs associated with autoimmune diseases within Th17-enhancers that precisely overlapped with the binding sites of transcription factors actively engaged in T-cell functions. Among the Th17-specific enhancers, we identified an enhancer in the intron of RORA and demonstrated that this enhancer positively regulates RORA transcription. Moreover, CRISPR-Cas9-mediated deletion of a transcription factor binding site-rich region within the identified RORA enhancer confirmed its role in regulating RORA transcription. These findings provide insights into the potential mechanism by which the RORA enhancer orchestrates Th17 differentiation., Competing Interests: Declaration of competing interest Alexander Marson is a co-founder of Arsenal Biosciences, Spotlight Therapeutics, and Survey Genomics, serves on the boards of directors at Spotlight Therapeutics and Survey Genomics, is a board observer (and former member of the board of directors) at Arsenal Biosciences, is a member of the scientific advisory boards of Arsenal Biosciences, Spotlight Therapeutics, Survey Genomics, NewLimit, Amgen, Tenaya, and Lightcast, owns stock in Arsenal Biosciences, Spotlight Therapeutics, NewLimit, Survey Genomics, PACT Pharma, Tenaya, and Lightcast, and has received fees from Arsenal Biosciences, Spotlight Therapeutics, NewLimit, 23andMe, PACT Pharma, Juno Therapeutics, Tenaya, Lightcast, Trizell, Vertex, Merck, Amgen, Genentech, AlphaSights, Rupert Case Management, Bernstein, and ALDA. A.M. is an investor in and informal advisor to Offline Ventures and a client of EPIQ. The Marson laboratory has received research support from Juno Therapeutics, Epinomics, Sanofi, GlaxoSmithKline, Gilead, and Anthem. All other authors declare no competing interests. The ChIP-seq and ATAC-seq raw and processed data has been submitted to GEO and can be accessed with the following super-series accession number: GSE243064., (Copyright © 2023. Published by Elsevier Inc.)

Published

2024

2. Long noncoding RNA LIRIL2R modulates FOXP3 levels and suppressive function of human CD4 + regulatory T cells by regulating IL2RA.

Author

Andrabi SBA, Kalim UU, Palani S, Khan MM, Khan MH, Fagersund J, Orpana J, Paulin N, Batkulwar K, Junttila S, Buchacher T, Grönroos T, Toikka L, Ammunet T, Sen P, Orešič M, Kumpulainen V, Tuomisto JEE, Sinha R, Marson A, Rasool O, Elo LL, and Lahesmaa R

Subjects

Humans, Epigenesis, Genetic, Gene Expression Regulation, Cell Differentiation genetics, RNA, Long Noncoding genetics, RNA, Long Noncoding metabolism, T-Lymphocytes, Regulatory immunology, T-Lymphocytes, Regulatory metabolism, Forkhead Transcription Factors genetics, Forkhead Transcription Factors metabolism, Interleukin-2 Receptor alpha Subunit genetics, Interleukin-2 Receptor alpha Subunit metabolism

Abstract

Regulatory T cells (Tregs) are central in controlling immune responses, and dysregulation of their function can lead to autoimmune disorders or cancer. Despite extensive studies on Tregs, the basis of epigenetic regulation of human Treg development and function is incompletely understood. Long intergenic noncoding RNAs (lincRNA)s are important for shaping and maintaining the epigenetic landscape in different cell types. In this study, we identified a gene on the chromosome 6p25.3 locus, encoding a lincRNA, that was up-regulated during early differentiation of human Tregs. The lincRNA regulated the expression of interleukin-2 receptor alpha (IL2RA), and we named it the lincRNA regulator of IL2RA (LIRIL2R). Through transcriptomics, epigenomics, and proteomics analysis of LIRIL2R-deficient Tregs, coupled with global profiling of LIRIL2R binding sites using chromatin isolation by RNA purification, followed by sequencing, we identified IL2RA as a target of LIRIL2R. This nuclear lincRNA binds upstream of the IL2RA locus and regulates its epigenetic landscape and transcription. CRISPR-mediated deletion of the LIRIL2R-bound region at the IL2RA locus resulted in reduced IL2RA expression. Notably, LIRIL2R deficiency led to reduced expression of Treg-signature genes (e.g., FOXP3 , CTLA4 , and PDCD1 ), upregulation of genes associated with effector T cells (e.g., SATB1 and GATA3 ), and loss of Treg-mediated suppression., Competing Interests: Competing interests statement:A.M. is a cofounder of Arsenal Biosciences, Function Bio, Spotlight Therapeutics, and Survey Genomics; serves on the boards of directors at Function Bio, Spotlight Therapeutics, and Survey Genomics; is a member of the scientific advisory boards of Arsenal Biosciences, Function Bio, Spotlight Therapeutics, Survey Genomics, NewLimit, Amgen, Tenaya, and Lightcast; owns stock in Arsenal Biosciences, Function Bio, Spotlight Therapeutics, NewLimit, Survey Genomics, Tenaya, and Lightcast; and has received fees from Arsenal Biosciences, Spotlight Therapeutics, NewLimit, Amgen, 23andMe, PACT Pharma, Juno Therapeutics, Tenaya, Survey Genomics, Lightcast, Gilead, Trizell, Vertex, Merck, Genentech, AlphaSights, Rupert Case Management, Bernstein, GLG, ClearView Healthcare Partners, and ALDA. A.M. is an investor in and informal advisor to Offline Ventures and a client of EPIQ. S.B.A.A., U.U.K., S.P., V.K., O.R., and R.L. are inventors in a European patent (Oligonucleotides for Modulating Regulatory T Cell Mediated Immunosuppression, patent number: WO2023242469A1) related to this manuscript. All other authors declare no competing interests.

Published

2024

3. Distinct cellular immune responses in children en route to type 1 diabetes with different first-appearing autoantibodies.

Author

Starskaia I, Valta M, Pietilä S, Suomi T, Pahkuri S, Kalim UU, Rasool O, Rydgren E, Hyöty H, Knip M, Veijola R, Ilonen J, Toppari J, Lempainen J, Elo LL, and Lahesmaa R

Subjects

Humans, Child, Female, Male, Child, Preschool, Adolescent, Killer Cells, Natural immunology, Leukocytes, Mononuclear immunology, Insulin immunology, Islets of Langerhans immunology, Disease Progression, Diabetes Mellitus, Type 1 immunology, Autoantibodies immunology, Autoantibodies blood, Glutamate Decarboxylase immunology, Immunity, Cellular

Abstract

Previous studies have revealed heterogeneity in the progression to clinical type 1 diabetes in children who develop islet-specific antibodies either to insulin (IAA) or glutamic acid decarboxylase (GADA) as the first autoantibodies. Here, we test the hypothesis that children who later develop clinical disease have different early immune responses, depending on the type of the first autoantibody to appear (GADA-first or IAA-first). We use mass cytometry for deep immune profiling of peripheral blood mononuclear cell samples longitudinally collected from children who later progressed to clinical disease (IAA-first, GADA-first, ≥2 autoantibodies first groups) and matched for age, sex, and HLA controls who did not, as part of the Type 1 Diabetes Prediction and Prevention study. We identify differences in immune cell composition of children who later develop disease depending on the type of autoantibodies that appear first. Notably, we observe an increase in CD161 expression in natural killer cells of children with ≥2 autoantibodies and validate this in an independent cohort. The results highlight the importance of endotype-specific analyses and are likely to contribute to our understanding of pathogenic mechanisms underlying type 1 diabetes development., (© 2024. The Author(s).)

Published

2024

4. HIC1 interacts with FOXP3 multi protein complex: Novel pleiotropic mechanisms to regulate human regulatory T cell differentiation and function.

Author

Andrabi SBA, Batkulwar K, Bhosale SD, Moulder R, Khan MH, Buchacher T, Khan MM, Arnkil I, Rasool O, Marson A, Kalim UU, and Lahesmaa R

Subjects

Female, Pregnancy, Humans, Protein Transport, Cell Differentiation genetics, Forkhead Transcription Factors genetics, Kruppel-Like Transcription Factors genetics, T-Lymphocytes, Regulatory, Immunosuppression Therapy, Lymphocyte Activation

Abstract

Transcriptional repressor, hypermethylated in cancer 1 (HIC1) participates in a range of important biological processes, such as tumor repression, immune suppression, embryonic development and epigenetic gene regulation. Further to these, we previously demonstrated that HIC1 provides a significant contribution to the function and development of regulatory T (Treg) cells. However, the mechanism by which it regulates these processes was not apparent. To address this question, we used affinity-purification mass spectrometry to characterize the HIC1 interactome in human Treg cells. Altogether 61 high-confidence interactors were identified, including IKZF3, which is a key transcription factor in the development of Treg cells. The biological processes associated with these interacting proteins include protein transport, mRNA processing, non-coding (ncRNA) transcription and RNA metabolism. The results revealed that HIC1 is part of a FOXP3-RUNX1-CBFB protein complex that regulates Treg signature genes thus improving our understanding of HIC1 function during early Treg cell differentiation., Competing Interests: Declaration of Competing Interest Authors declare no competing interests. A.M. is a cofounder of Arsenal Biosciences, Spotlight Therapeutics, and Survey Genomics, serves on the boards of directors at Spotlight Therapeutics and Survey Genomics, is a board observer (and former member of the board of directors) at Arsenal Biosciences, is a member of the scientific advisory boards of Arsenal Biosciences, Spotlight Therapeutics, Survey Genomics, NewLimit, Amgen and Tenaya, owns stock in Arsenal Biosciences, Spotlight Therapeutics, NewLimit, Survey Genomics, PACT Pharma, and Tenaya and has received fees from Arsenal Biosciences, Spotlight Therapeutics, NewLimit, 23andMe, PACT Pharma, Juno Therapeutics, Trizell, Vertex, Merck, Amgen, Genentech, AlphaSights, Rupert Case Management, Bernstein and ALDA. A.M. is an investor in and informal advisor to Offline Ventures and a client of EPIQ. The Marson laboratory has received research support from Juno Therapeutics, Epinomics, Sanofi, GlaxoSmithKline, Gilead and Anthem., (Copyright © 2023. Published by Elsevier B.V.)

Published

2023

5. Gene expression signature predicts rate of type 1 diabetes progression.

Author

Suomi T, Starskaia I, Kalim UU, Rasool O, Jaakkola MK, Grönroos T, Välikangas T, Brorsson C, Mazzoni G, Bruggraber S, Overbergh L, Dunger D, Peakman M, Chmura P, Brunak S, Schulte AM, Mathieu C, Knip M, Lahesmaa R, and Elo LL

Subjects

Humans, Transcriptome, Disease Progression, Autoantibodies, Diabetes Mellitus, Type 1, Autoimmune Diseases

Abstract

Background: Type 1 diabetes is a complex heterogenous autoimmune disease without therapeutic interventions available to prevent or reverse the disease. This study aimed to identify transcriptional changes associated with the disease progression in patients with recent-onset type 1 diabetes., Methods: Whole-blood samples were collected as part of the INNODIA study at baseline and 12 months after diagnosis of type 1 diabetes. We used linear mixed-effects modelling on RNA-seq data to identify genes associated with age, sex, or disease progression. Cell-type proportions were estimated from the RNA-seq data using computational deconvolution. Associations to clinical variables were estimated using Pearson's or point-biserial correlation for continuous and dichotomous variables, respectively, using only complete pairs of observations., Findings: We found that genes and pathways related to innate immunity were downregulated during the first year after diagnosis. Significant associations of the gene expression changes were found with ZnT8A autoantibody positivity. Rate of change in the expression of 16 genes between baseline and 12 months was found to predict the decline in C-peptide at 24 months. Interestingly and consistent with earlier reports, increased B cell levels and decreased neutrophil levels were associated with the rapid progression., Interpretation: There is considerable individual variation in the rate of progression from appearance of type 1 diabetes-specific autoantibodies to clinical disease. Patient stratification and prediction of disease progression can help in developing more personalised therapeutic strategies for different disease endotypes., Funding: A full list of funding bodies can be found under Acknowledgments., Competing Interests: Declaration of interests CM serves or has served on the advisory panel for ActoBio Therapeutics, AstraZeneca, Avotres, Boehringer Ingelheim, Eli Lilly and Company, Imcyse, Insulet, Mannkind, Medtronic, Merck Sharp and Dohme Ltd., Novartis, Novo Nordisk, Pfizer, Roche, Sandoz, Sanofi, Vertex, and Zealand Pharma. CM serves or has served on the speakers bureau for AstraZeneca, Boehringer Ingelheim, Eli Lilly and Company, Novartis, Novo Nordisk, and Sanofi. “T.G. was supported by Academy of Finland, Tampere University and University of Turku”., (Copyright © 2023 The Authors. Published by Elsevier B.V. All rights reserved.)

Published

2023

6. Permutation-based significance analysis reduces the type 1 error rate in bisulphite sequencing data analysis of human umbilical cord blood samples.

Author

Laajala E, Halla-Aho V, Grönroos T, Kalim UU, Vähä-Mäkilä M, Nurmio M, Kallionpää H, Lietzén N, Mykkänen J, Rasool O, Toppari J, Orešič M, Knip M, Lund R, Lahesmaa R, and Lähdesmäki H

Subjects

Infant, Newborn, Pregnancy, Female, Humans, Data Analysis, Sequence Analysis, DNA, DNA Methylation, Fetal Blood metabolism

Abstract

DNA methylation patterns are largely established in-utero and might mediate the impacts of in-utero conditions on later health outcomes. Associations between perinatal DNA methylation marks and pregnancy-related variables, such as maternal age and gestational weight gain, have been earlier studied with methylation microarrays, which typically cover less than 2% of human CpG sites. To detect such associations outside these regions, we chose the bisulphite sequencing approach. We collected and curated clinical data on 200 newborn infants; whose umbilical cord blood samples were analysed with the reduced representation bisulphite sequencing (RRBS) method. A generalized linear mixed-effects model was fit for each high coverage CpG site, followed by spatial and multiple testing adjustment of P values to identify differentially methylated cytosines (DMCs) and regions (DMRs) associated with clinical variables, such as maternal age, mode of delivery, and birth weight. Type 1 error rate was then evaluated with a permutation analysis. We discovered a strong inflation of spatially adjusted P values through the permutation analysis, which we then applied for empirical type 1 error control. The inflation of P values was caused by a common method for spatial adjustment and DMR detection, implemented in tools comb-p and RADMeth. Based on empirically estimated significance thresholds, very little differential methylation was associated with any of the studied clinical variables, other than sex. With this analysis workflow, the sex-associated differentially methylated regions were highly reproducible across studies, technologies, and statistical models.

Published

2022

7. Umbilical cord blood DNA methylation in children who later develop type 1 diabetes.

Author

Laajala E, Kalim UU, Grönroos T, Rasool O, Halla-Aho V, Konki M, Kattelus R, Mykkänen J, Nurmio M, Vähä-Mäkilä M, Kallionpää H, Lietzén N, Ghimire BR, Laiho A, Hyöty H, Elo LL, Ilonen J, Knip M, Lund RJ, Orešič M, Veijola R, Lähdesmäki H, Toppari J, and Lahesmaa R

Subjects

Autoantibodies, Child, Child, Preschool, DNA Methylation genetics, Female, Fetal Blood metabolism, Glutamate Decarboxylase, Humans, Pregnancy, Diabetes Mellitus, Type 1

Abstract

Aims/hypothesis: Distinct DNA methylation patterns have recently been observed to precede type 1 diabetes in whole blood collected from young children. Our aim was to determine whether perinatal DNA methylation is associated with later progression to type 1 diabetes., Methods: Reduced representation bisulphite sequencing (RRBS) analysis was performed on umbilical cord blood samples collected within the Finnish Type 1 Diabetes Prediction and Prevention (DIPP) Study. Children later diagnosed with type 1 diabetes and/or who tested positive for multiple islet autoantibodies (n = 43) were compared with control individuals (n = 79) who remained autoantibody-negative throughout the DIPP follow-up until 15 years of age. Potential confounding factors related to the pregnancy and the mother were included in the analysis., Results: No differences in the umbilical cord blood methylation patterns were observed between the cases and controls at a false discovery rate <0.05., Conclusions/interpretation: Based on our results, differences between children who progress to type 1 diabetes and those who remain healthy throughout childhood are not yet present in the perinatal DNA methylome. However, we cannot exclude the possibility that such differences would be found in a larger dataset., (© 2022. The Author(s).)

Published

2022

8. Long Intergenic Noncoding RNA MIAT as a Regulator of Human Th17 Cell Differentiation.

Author

Khan MM, Khan MH, Kalim UU, Khan S, Junttila S, Paulin N, Kong L, Rasool O, Elo LL, and Lahesmaa R

Subjects

Cell Differentiation genetics, Chromatin genetics, Humans, Lymphocyte Activation, Myocardial Infarction genetics, RNA, Long Noncoding genetics

Abstract

T helper 17 (Th17) cells protect against fungal and bacterial infections and are implicated in autoimmunity. Several long intergenic noncoding RNAs (lincRNA) are induced during Th17 differentiation, however, their contribution to Th17 differentiation is poorly understood. We aimed to characterize the function of the lincRNA Myocardial Infarction Associated Transcript (MIAT) during early human Th17 cell differentiation. We found MIAT to be upregulated early after induction of human Th17 cell differentiation along with an increase in the chromatin accessibility at the gene locus. STAT3, a key regulator of Th17 differentiation, directly bound to the MIAT promoter and induced its expression during the early stages of Th17 cell differentiation. MIAT resides in the nucleus and regulates the expression of several key Th17 genes, including IL17A, IL17F, CCR6 and CXCL13, possibly by altering the chromatin accessibility of key loci, including IL17A locus. Further, MIAT regulates the expression of protein kinase C alpha (PKCα), an upstream regulator of IL17A. A reanalysis of published single-cell RNA-seq data showed that MIAT was expressed in T cells from the synovium of RA patients. Our results demonstrate that MIAT contributes to human Th17 differentiation by upregulating several genes implicated in Th17 differentiation. High MIAT expression in T cells of RA patient synovia suggests a possible role of MIAT in Th17 mediated autoimmune pathologies., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2022 Khan, Khan, Kalim, Khan, Junttila, Paulin, Kong, Rasool, Elo and Lahesmaa.)

Published

2022

9. Early DNA methylation changes in children developing beta cell autoimmunity at a young age.

Author

Starskaia I, Laajala E, Grönroos T, Härkönen T, Junttila S, Kattelus R, Kallionpää H, Laiho A, Suni V, Tillmann V, Lund R, Elo LL, Lähdesmäki H, Knip M, Kalim UU, and Lahesmaa R

Subjects

Autoantibodies genetics, Autoimmunity genetics, CD8-Positive T-Lymphocytes, Child, CpG Islands, Epigenesis, Genetic genetics, Humans, Leukocytes, Mononuclear, DNA Methylation genetics, Diabetes Mellitus, Type 1 genetics

Abstract

Aims/hypothesis: Type 1 diabetes is a chronic autoimmune disease of complex aetiology, including a potential role for epigenetic regulation. Previous epigenomic studies focused mainly on clinically diagnosed individuals. The aim of the study was to assess early DNA methylation changes associated with type 1 diabetes already before the diagnosis or even before the appearance of autoantibodies., Methods: Reduced representation bisulphite sequencing (RRBS) was applied to study DNA methylation in purified CD4 + T cell, CD8 + T cell and CD4 - CD8 - cell fractions of 226 peripheral blood mononuclear cell samples longitudinally collected from seven type 1 diabetes-specific autoantibody-positive individuals and control individuals matched for age, sex, HLA risk and place of birth. We also explored correlations between DNA methylation and gene expression using RNA sequencing data from the same samples. Technical validation of RRBS results was performed using pyrosequencing., Results: We identified 79, 56 and 45 differentially methylated regions in CD4 + T cells, CD8 + T cells and CD4 - CD8 - cell fractions, respectively, between type 1 diabetes-specific autoantibody-positive individuals and control participants. The analysis of pre-seroconversion samples identified DNA methylation signatures at the very early stage of disease, including differential methylation at the promoter of IRF5 in CD4 + T cells. Further, we validated RRBS results using pyrosequencing at the following CpG sites: chr19:18118304 in the promoter of ARRDC2; chr21:47307815 in the intron of PCBP3; and chr14:81128398 in the intergenic region near TRAF3 in CD4 + T cells., Conclusions/interpretation: These preliminary results provide novel insights into cell type-specific differential epigenetic regulation of genes, which may contribute to type 1 diabetes pathogenesis at the very early stage of disease development. Should these findings be validated, they may serve as a potential signature useful for disease prediction and management., (© 2022. The Author(s).)

Published

2022

10. Type 1 Diabetes in Children With Genetic Risk May Be Predicted Very Early With a Blood miRNA.

Author

Suomi T, Kalim UU, Rasool O, Laiho A, Kallionpää H, Vähä-Mäkilä M, Nurmio M, Mykkänen J, Härkönen T, Hyöty H, Ilonen J, Veijola R, Toppari J, Knip M, Elo LL, and Lahesmaa R

Subjects

Child, Humans, Risk Factors, Diabetes Mellitus, Type 1 genetics, Diabetes Mellitus, Type 2 genetics, MicroRNAs genetics

Published

2022

11. PP2A and Its Inhibitors in Helper T-Cell Differentiation and Autoimmunity.

Author

Khan MM, Kalim UU, Khan MH, and Lahesmaa R

Subjects

Animals, Humans, Protein Processing, Post-Translational immunology, Autoimmunity, Cell Differentiation immunology, Protein Phosphatase 2 immunology, T-Lymphocytes, Helper-Inducer immunology

Abstract

Protein phosphatase 2A (PP2A) is a highly complex heterotrimeric Ser/Thr phosphatase that regulates many cellular processes. The role of PP2A as a tumor suppressor has been extensively studied and reviewed. However, emerging evidence suggests PP2A constrains inflammatory responses and is important in autoimmune and neuroinflammatory diseases. Here, we reviewed the existing literature on the role of PP2A in T-cell differentiation and autoimmunity. We have also discussed the modulation of PP2A activity by endogenous inhibitors and its small-molecule activators as potential therapeutic approaches against autoimmunity., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2022 Khan, Kalim, Khan and Lahesmaa.)

Published

2022

12. Quantitative genome-scale metabolic modeling of human CD4 + T cell differentiation reveals subset-specific regulation of glycosphingolipid pathways.

Author

Sen P, Andrabi SBA, Buchacher T, Khan MM, Kalim UU, Lindeman TM, Alves MA, Hinkkanen V, Kemppainen E, Dickens AM, Rasool O, Hyötyläinen T, Lahesmaa R, and Orešič M

Subjects

CD4-Positive T-Lymphocytes metabolism, Genome, Human, Humans, Lymphocyte Activation, T-Lymphocyte Subsets immunology, T-Lymphocyte Subsets metabolism, CD4-Positive T-Lymphocytes immunology, Cell Differentiation, Ceramides metabolism, Glycosphingolipids metabolism, Metabolome, T-Lymphocytes, Regulatory immunology, Th17 Cells immunology

Abstract

T cell activation, proliferation, and differentiation involve metabolic reprogramming resulting from the interplay of genes, proteins, and metabolites. Here, we aim to understand the metabolic pathways involved in the activation and functional differentiation of human CD4 + T cell subsets (T helper [Th]1, Th2, Th17, and induced regulatory T [iTreg] cells). Here, we combine genome-scale metabolic modeling, gene expression data, and targeted and non-targeted lipidomics experiments, together with in vitro gene knockdown experiments, and show that human CD4 + T cells undergo specific metabolic changes during activation and functional differentiation. In addition, we confirm the importance of ceramide and glycosphingolipid biosynthesis pathways in Th17 differentiation and effector functions. Through in vitro gene knockdown experiments, we substantiate the requirement of serine palmitoyltransferase (SPT), a de novo sphingolipid pathway in the expression of proinflammatory cytokines (interleukin [IL]-17A and IL17F) by Th17 cells. Our findings provide a comprehensive resource for selective manipulation of CD4 + T cells under disease conditions characterized by an imbalance of Th17/natural Treg (nTreg) cells., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2021 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2021