Warning: Undefined array key "mm" in /www/wwwroot/www.ai-bt.com/si.php on line 10 Deprecated: trim(): Passing null to parameter #1 ($string) of type string is deprecated in /www/wwwroot/www.ai-bt.com/si.php on line 10 Transcriptome dynamics of CD4+ T cells during malaria maps gradual transit from effector to memory.

Literature DB >> 33046889

Transcriptome dynamics of CD4⁺ T cells during malaria maps gradual transit from effector to memory.

Megan S F Soon¹, Hyun Jae Lee^1,2, Jessica A Engel¹, Jasmin Straube¹, Bryce S Thomas¹, Clara P S Pernold¹, Lachlan S Clarke¹, Pawat Laohamonthonkul¹, Rohit N Haldar¹, Cameron G Williams^1,2, Lianne I M Lansink^1,2, Marcela L Moreira², Michael Bramhall², Lambros T Koufariotis¹, Scott Wood¹, Xi Chen^3,4,5, Kylie R James^4,5, Tapio Lönnberg⁶, Steven W Lane¹, Gabrielle T Belz^7,8,9, Christian R Engwerda¹, David S Khoury¹⁰, Miles P Davenport¹⁰, Valentine Svensson¹¹, Sarah A Teichmann^12,13, Ashraful Haque^14,15.

Abstract

The dynamics of CD4+ T cell memory development remain to be examined at genome scale. In malaria-endemic regions, antimalarial chemoprevention protects long after its cessation and associates with effects on CD4+ T cells. We applied single-cell RNA sequencing and computational modelling to track memory development during Plasmodium infection and treatment. In the absence of central memory precursors, two trajectories developed as T helper 1 (TH1) and follicular helper T (TFH) transcriptomes contracted and partially coalesced over three weeks. Progeny of single clones populated TH1 and TFH trajectories, and fate-mapping suggested that there was minimal lineage plasticity. Relationships between TFH and central memory were revealed, with antimalarials modulating these responses and boosting TH1 recall. Finally, single-cell epigenomics confirmed that heterogeneity among effectors was partially reset in memory. Thus, the effector-to-memory transition in CD4+ T cells is gradual during malaria and is modulated by antiparasitic drugs. Graphical user interfaces are presented for examining gene-expression dynamics and gene-gene correlations ( http://haquelab.mdhs.unimelb.edu.au/cd4_memory/ ).

Entities: Chemical Disease Gene

Mesh：

Substances：

Year: 2020 PMID： 33046889 DOI： 10.1038/s41590-020-0800-8

Source DB: PubMed Journal: Nat Immunol ISSN： 1529-2908 Impact factor: 25.606

59 in total

1. Differential expression of Ly6C and T-bet distinguish effector and memory Th1 CD4(+) cell properties during viral infection.

Authors: Heather D Marshall; Anmol Chandele; Yong Woo Jung; Hailong Meng; Amanda C Poholek; Ian A Parish; Rachel Rutishauser; Weiguo Cui; Steven H Kleinstein; Joe Craft; Susan M Kaech
Journal: Immunity Date: 2011-10-20 Impact factor: 31.745

2. Opposing signals from the Bcl6 transcription factor and the interleukin-2 receptor generate T helper 1 central and effector memory cells.

Authors: Marion Pepper; Antonio J Pagán; Botond Z Igyártó; Justin J Taylor; Marc K Jenkins
Journal: Immunity Date: 2011-10-20 Impact factor: 31.745

3. The Emergence and Functional Fitness of Memory CD4⁺ T Cells Require the Transcription Factor Thpok.

Authors: Thomas Ciucci; Melanie S Vacchio; Yayi Gao; Francesco Tomassoni Ardori; Julian Candia; Monika Mehta; Yongmei Zhao; Bao Tran; Marion Pepper; Lino Tessarollo; Dorian B McGavern; Rémy Bosselut
Journal: Immunity Date: 2019-01-09 Impact factor: 31.745

4. Early effector cells survive the contraction phase in malaria infection and generate both central and effector memory T cells.

Authors: Michael M Opata; Victor H Carpio; Samad A Ibitokou; Brian E Dillon; Joshua M Obiero; Robin Stephens
Journal: J Immunol Date: 2015-04-24 Impact factor: 5.422

5. Distinct memory CD4+ T cells with commitment to T follicular helper- and T helper 1-cell lineages are generated after acute viral infection.

Authors: J Scott Hale; Ben Youngblood; Donald R Latner; Ata Ur Rasheed Mohammed; Lilin Ye; Rama S Akondy; Tuoqi Wu; Smita S Iyer; Rafi Ahmed
Journal: Immunity Date: 2013-04-11 Impact factor: 31.745

Review 6. Immunity to malaria: more questions than answers.

Authors: Jean Langhorne; Francis M Ndungu; Anne-Marit Sponaas; Kevin Marsh
Journal: Nat Immunol Date: 2008-07 Impact factor: 25.606

7. Memory CD4 T cells emerge from effector T-cell progenitors.

Authors: Laurie E Harrington; Karen M Janowski; James R Oliver; Allan J Zajac; Casey T Weaver
Journal: Nature Date: 2008-03-05 Impact factor: 49.962

8. Most microbe-specific naïve CD4⁺ T cells produce memory cells during infection.

Authors: Noah J Tubo; Brian T Fife; Antonio J Pagan; Dmitri I Kotov; Michael F Goldberg; Marc K Jenkins
Journal: Science Date: 2016-01-29 Impact factor: 47.728

9. Origin and differentiation of human memory CD8 T cells after vaccination.

Authors: Rama S Akondy; Mark Fitch; Srilatha Edupuganti; Shu Yang; Haydn T Kissick; Kelvin W Li; Ben A Youngblood; Hossam A Abdelsamed; Donald J McGuire; Kristen W Cohen; Gabriela Alexe; Shashi Nagar; Megan M McCausland; Satish Gupta; Pramila Tata; W Nicholas Haining; M Juliana McElrath; David Zhang; Bin Hu; William J Greenleaf; Jorg J Goronzy; Mark J Mulligan; Marc Hellerstein; Rafi Ahmed
Journal: Nature Date: 2017-12-13 Impact factor: 69.504

10. Dissecting the heterogeneity of DENV vaccine-elicited cellular immunity using single-cell RNA sequencing and metabolic profiling.

Authors: Adam T Waickman; Kaitlin Victor; Tao Li; Kristin Hatch; Wiriya Rutvisuttinunt; Carey Medin; Benjamin Gabriel; Richard G Jarman; Heather Friberg; Jeffrey R Currier
Journal: Nat Commun Date: 2019-08-14 Impact factor: 14.919

8 in total

Review 1. A plate-based single-cell ATAC-seq workflow for fast and robust profiling of chromatin accessibility.

Authors: Wei Xu; Yi Wen; Yingying Liang; Qiushi Xu; Xuefei Wang; Wenfei Jin; Xi Chen
Journal: Nat Protoc Date: 2021-07-19 Impact factor: 13.491

2. A CD4⁺ T cell reference map delineates subtype-specific adaptation during acute and chronic viral infections.

Authors: Thomas Ciucci; Santiago J Carmona; Massimo Andreatta; Ariel Tjitropranoto; Zachary Sherman; Michael C Kelly
Journal: Elife Date: 2022-07-13 Impact factor: 8.713

3. Tfh-cell-derived interleukin 21 sustains effector CD8⁺ T cell responses during chronic viral infection.

Authors: Ryan Zander; Moujtaba Y Kasmani; Yao Chen; Paytsar Topchyan; Jian Shen; Shikan Zheng; Robert Burns; Jennifer Ingram; Can Cui; Nikhil Joshi; Joseph Craft; Allan Zajac; Weiguo Cui
Journal: Immunity Date: 2022-02-24 Impact factor: 43.474

Review 4. Anti-malarial humoral immunity: the long and short of it.

Authors: Kai J Rogers; Rahul Vijay; Noah S Butler
Journal: Microbes Infect Date: 2021-03-05 Impact factor: 2.700

5. Stable Epigenetic Programming of Effector and Central Memory CD4 T Cells Occurs Within 7 Days of Antigen Exposure In Vivo.

Authors: Sarah L Bevington; Remi Fiancette; Dominika W Gajdasik; Peter Keane; Jake K Soley; Claire M Willis; Daniel J L Coleman; David R Withers; Peter N Cockerill
Journal: Front Immunol Date: 2021-05-24 Impact factor: 7.561

6. Properties and Roles of γδT Cells in Plasmodium yoelii nigeriensis NSM Infected C57BL/6 Mice.

Authors: Hongyan Xie; Shihao Xie; Mei Wang; Haixia Wei; He Huang; Anqi Xie; Jiajie Li; Chao Fang; Feihu Shi; Quan Yang; Yanwei Qi; Zhinan Yin; Xinhua Wang; Jun Huang
Journal: Front Cell Infect Microbiol Date: 2022-01-20 Impact factor: 5.293

Review 7. Impact of single-cell RNA sequencing on understanding immune regulation.

Authors: Xueli Hu; Xikun Zhou
Journal: J Cell Mol Med Date: 2022-07-30 Impact factor: 5.295

8. Dissecting the dynamic transcriptional landscape of early T helper cell differentiation into Th1, Th2, and Th1/2 hybrid cells.

Authors: Philipp Burt; Michael Peine; Caroline Peine; Zuzanna Borek; Sebastian Serve; Michael Floßdorf; Ahmed N Hegazy; Thomas Höfer; Max Löhning; Kevin Thurley
Journal: Front Immunol Date: 2022-08-16 Impact factor: 8.786

8 in total