Your search keyword '"Davies, Jessica L [0000-0002-8888-1441]"' showing total 2 results

1. Therapeutically expanded human regulatory T-cells are super-suppressive due to HIF1A induced expression of CD73

Author

Daniel B. Rainbow, Lorna B. Jarvis, Valerie Coppard, Hani S Mousa, Joanne L. Jones, Alasdair Coles, Zoya Georgieva, Fadi Issa, Kourosh Saeb-Parsy, Krishnaa T. Mahbubani, Stefano Pluchino, Tom Ashmore, Sarah Howlett, Julian L. Griffin, Luca Peruzzotti-Jametti, Linda S. Wicker, Aletta Van Den Bosch, Joanna Hester, Harpreet Kaur Mullay, James T. Grist, Jessica L. Davies, Jarvis, Lorna B [0000-0002-5760-0125], Rainbow, Daniel B [0000-0003-4931-3289], Davies, Jessica L [0000-0002-8888-1441], Hester, Joanna [0000-0002-7466-3849], Pluchino, Stefano [0000-0002-6267-9472], Mahbubani, Krishnaa T [0000-0002-1327-2334], Griffin, Julian L [0000-0003-1336-7744], Saeb-Parsy, Kourosh [0000-0002-0633-3696], Issa, Fadi [0000-0002-8279-7732], Wicker, Linda S [0000-0001-7771-0324], Jones, Joanne L [0000-0003-4974-1371], Apollo - University of Cambridge Repository, Mousa, Hani S [0000-0002-8327-7114], Jarvis, Lorna B. [0000-0002-5760-0125], Rainbow, Daniel B. [0000-0003-4931-3289], Davies, Jessica L. [0000-0002-8888-1441], Mahbubani, Krishnaa T. [0000-0002-1327-2334], Griffin, Julian L. [0000-0003-1336-7744], Wicker, Linda S. [0000-0001-7771-0324], and Jones, Joanne L. [0000-0003-4974-1371]

Subjects

Male, Adoptive cell transfer, Autoimmune diseases, Medicine (miscellaneous), medicine.disease_cause, T-Lymphocytes, Regulatory, Graft-versus-host disease, Autoimmunity, Transcriptome, 13/1, 0302 clinical medicine, Biology (General), 631/250/24/1313, 5'-Nucleotidase, 0303 health sciences, 631/250/24/1529, 631/250/251/1574, hemic and immune systems, Regulatory T cells, 3. Good health, 13/31, 030220 oncology & carcinogenesis, 631/250/1619/554/1898/1271, 38/39, 64/60, Female, General Agricultural and Biological Sciences, medicine.drug, QH301-705.5, 13/106, chemical and pharmacologic phenomena, Biology, GPI-Linked Proteins, General Biochemistry, Genetics and Molecular Biology, Article, 03 medical and health sciences, 13/21, medicine, Humans, 030304 developmental biology, 82, 82/58, Hypoxia-Inducible Factor 1, alpha Subunit, Adenosine, Transplantation, HIF1A, Gene Expression Regulation, Anaerobic glycolysis, Cancer research, Ex vivo, Immunosuppression

Abstract

The adoptive transfer of regulatory T-cells (Tregs) is a promising therapeutic approach in transplantation and autoimmunity. However, because large cell numbers are needed to achieve a therapeutic effect, in vitro expansion is required. By comparing their function, phenotype and transcriptomic profile against ex vivo Tregs, we demonstrate that expanded human Tregs switch their metabolism to aerobic glycolysis and show enhanced suppressive function through hypoxia-inducible factor 1-alpha (HIF1A) driven acquisition of CD73 expression. In conjunction with CD39, CD73 expression enables expanded Tregs to convert ATP to immunosuppressive adenosine. We conclude that for maximum therapeutic benefit, Treg expansion protocols should be optimised for CD39/CD73 co-expression., Jarvis et al demonstrate that expanded human Tregs switch their metabolism to aerobic glycolysis and show enhanced suppressive function through hypoxia-inducible factor 1-alpha (HIF1A)-driven acquisition of CD73 expression, which along with CD39, enables expanded Tregs to convert ATP to immunosuppressive adenosine. Given this, the data suggests that Treg expansion protocols should be optimised for CD39/CD73 co-expression to enhance therapeutic potential.

Published

2020

2. Mouse fetal growth restriction through parental and fetal immune gene variation and intercellular communications cascade

Author

Kaur, Gurman, Porter, Caroline BM, Ashenberg, Orr, Lee, Jack, Riesenfeld, Samantha J, Hofree, Matan, Aggelakopoulou, Maria, Subramanian, Ayshwarya, Kuttikkatte, Subita Balaram, Attfield, Kathrine E, Desel, Christiane AE, Davies, Jessica L, Evans, Hayley G, Avraham-Davidi, Inbal, Nguyen, Lan T, Dionne, Danielle A, Neumann, Anna E, Jensen, Lise Torp, Barber, Thomas R, Soilleux, Elizabeth, Carrington, Mary, McVean, Gil, Rozenblatt-Rosen, Orit, Regev, Aviv, Fugger, Lars, Kaur, Gurman [0000-0001-7722-3956], Riesenfeld, Samantha J [0000-0001-9144-021X], Hofree, Matan [0000-0001-8368-0299], Subramanian, Ayshwarya [0000-0002-4134-7612], Attfield, Kathrine E [0000-0003-3387-521X], Desel, Christiane AE [0000-0003-2029-3851], Davies, Jessica L [0000-0002-8888-1441], Avraham-Davidi, Inbal [0000-0001-7118-9179], Neumann, Anna E [0000-0001-7115-8305], Soilleux, Elizabeth [0000-0002-4032-7249], Carrington, Mary [0000-0002-2692-2180], McVean, Gil [0000-0002-5012-4162], Rozenblatt-Rosen, Orit [0000-0001-6313-3570], Fugger, Lars [0000-0003-2883-3226], and Apollo - University of Cambridge Repository

Subjects

123, 631/250/2504, General Physics and Astronomy, Cell Communication, HLA-C Antigens, General Biochemistry, Genetics and Molecular Biology, 14/32, Mice, 13/1, Fetus, Pregnancy, Animals, 45/91, Fetal Growth Retardation, Multidisciplinary, 45, article, General Chemistry, 631/208/248, Trophoblasts, 692/4017, 13/31, 631/250/1619/382, 38/77, Female, 38/39, 64/60

Abstract

Fetal growth restriction (FGR) affects 5–10% of pregnancies, and can have serious consequences for both mother and child. Prevention and treatment are limited because FGR pathogenesis is poorly understood. Genetic studies implicateKIRandHLAgenes in FGR, however, linkage disequilibrium, genetic influence from both parents, and challenges with investigating human pregnancies make the risk alleles and their functional effects difficult to map. Here, we demonstrate that the interaction between the maternal KIR2DL1, expressed on uterine natural killer (NK) cells, and the paternally inherited HLA-C*0501, expressed on fetal trophoblast cells, leads to FGR in a humanized mouse model. We show that the KIR2DL1 and C*0501 interaction leads to pathogenic uterine arterial remodeling and modulation of uterine NK cell function. This initial effect cascades to altered transcriptional expression and intercellular communication at the maternal-fetal interface. These findings provide mechanistic insight into specific FGR risk alleles, and provide avenues of prevention and treatment.

Published

2022