Your search keyword '"Loudon, Kevin"' showing total 4 results

1. Single-cell transcriptomes from human kidneys reveal the cellular identity of renal tumors

Author

Young, Matthew D, Mitchell, Thomas J, Vieira Braga, Felipe A, Tran, Maxine GB, Stewart, Benjamin J, Ferdinand, John R, Collord, Grace, Botting, Rachel A, Popescu, Dorin-Mirel, Loudon, Kevin W, Vento-Tormo, Roser, Stephenson, Emily, Cagan, Alex, Farndon, Sarah J, Del Castillo Velasco-Herrera, Martin, Guzzo, Charlotte, Richoz, Nathan, Mamanova, Lira, Aho, Tevita, Armitage, James N, Riddick, Antony CP, Mushtaq, Imran, Farrell, Stephen, Rampling, Dyanne, Nicholson, James, Filby, Andrew, Burge, Johanna, Lisgo, Steven, Maxwell, Patrick H, Lindsay, Susan, Warren, Anne Y, Stewart, Grant D, Sebire, Neil, Coleman, Nicholas, Haniffa, Muzlifah, Teichmann, Sarah A, Clatworthy, Menna, and Behjati, Sam

Subjects

Adult, Genetic Variation, Humans, Single-Cell Analysis, Child, Kidney, Transcriptome, Carcinoma, Renal Cell, Wilms Tumor, Kidney Neoplasms, 3. Good health

Abstract

Messenger RNA encodes cellular function and phenotype. In the context of human cancer, it defines the identities of malignant cells and the diversity of tumor tissue. We studied 72,501 single-cell transcriptomes of human renal tumors and normal tissue from fetal, pediatric, and adult kidneys. We matched childhood Wilms tumor with specific fetal cell types, thus providing evidence for the hypothesis that Wilms tumor cells are aberrant fetal cells. In adult renal cell carcinoma, we identified a canonical cancer transcriptome that matched a little-known subtype of proximal convoluted tubular cell. Analyses of the tumor composition defined cancer-associated normal cells and delineated a complex vascular endothelial growth factor (VEGF) signaling circuit. Our findings reveal the precise cellular identities and compositions of human kidney tumors.

2. Regulatory T Cell Responses in Participants with Type 1 Diabetes after a Single Dose of Interleukin-2: A Non-Randomised, Open Label, Adaptive Dose-Finding Trial

Author

Todd, John A, Evangelou, Marina, Cutler, Antony J, Pekalski, Marcin L, Walker, Neil M, Stevens, Helen E, Porter, Linsey, Smyth, Deborah J, Rainbow, Daniel B, Ferreira, Ricardo C, Esposito, Laura, Hunter, Kara MD, Loudon, Kevin, Irons, Kathryn, Yang, Jennie H, Bell, Charles JM, Schuilenburg, Helen, Heywood, James, Challis, Ben, Neupane, Sankalpa, Clarke, Pamela, Coleman, Gillian, Dawson, Sarah, Goymer, Donna, Anselmiova, Katerina, Kennet, Jane, Brown, Judy, Caddy, Sarah L, Lu, Jia, Greatorex, Jane, Goodfellow, Ian, Wallace, Chris, Tree, Tim I, Evans, Mark, Mander, Adrian P, Bond, Simon, Wicker, Linda S, and Waldron-Lynch, Frank

Subjects

Adult, Male, Adolescent, Dose-Response Relationship, Drug, Middle Aged, T-Lymphocytes, Regulatory, Recombinant Proteins, 3. Good health, Immunophenotyping, Eosinophils, Killer Cells, Natural, Young Adult, Diabetes Mellitus, Type 1, Humans, Interleukin-2, Female, Lymphocyte Count, Chemokines, Inflammation Mediators, Biomarkers

Abstract

BACKGROUND: Interleukin-2 (IL-2) has an essential role in the expansion and function of CD4+ regulatory T cells (Tregs). Tregs reduce tissue damage by limiting the immune response following infection and regulate autoreactive CD4+ effector T cells (Teffs) to prevent autoimmune diseases, such as type 1 diabetes (T1D). Genetic susceptibility to T1D causes alterations in the IL-2 pathway, a finding that supports Tregs as a cellular therapeutic target. Aldesleukin (Proleukin; recombinant human IL-2), which is administered at high doses to activate the immune system in cancer immunotherapy, is now being repositioned to treat inflammatory and autoimmune disorders at lower doses by targeting Tregs. METHODS AND FINDINGS: To define the aldesleukin dose response for Tregs and to find doses that increase Tregs physiologically for treatment of T1D, a statistical and systematic approach was taken by analysing the pharmacokinetics and pharmacodynamics of single doses of subcutaneous aldesleukin in the Adaptive Study of IL-2 Dose on Regulatory T Cells in Type 1 Diabetes (DILT1D), a single centre, non-randomised, open label, adaptive dose-finding trial with 40 adult participants with recently diagnosed T1D. The primary endpoint was the maximum percentage increase in Tregs (defined as CD3+CD4+CD25highCD127low) from the baseline frequency in each participant measured over the 7 d following treatment. There was an initial learning phase with five pairs of participants, each pair receiving one of five pre-assigned single doses from 0.04 × 106 to 1.5 × 106 IU/m2, in order to model the dose-response curve. Results from each participant were then incorporated into interim statistical modelling to target the two doses most likely to induce 10% and 20% increases in Treg frequencies. Primary analysis of the evaluable population (n = 39) found that the optimal doses of aldesleukin to induce 10% and 20% increases in Tregs were 0.101 × 106 IU/m2 (standard error [SE] = 0.078, 95% CI = -0.052, 0.254) and 0.497 × 106 IU/m2 (SE = 0.092, 95% CI = 0.316, 0.678), respectively. On analysis of secondary outcomes, using a highly sensitive IL-2 assay, the observed plasma concentrations of the drug at 90 min exceeded the hypothetical Treg-specific therapeutic window determined in vitro (0.015-0.24 IU/ml), even at the lowest doses (0.040 × 106 and 0.045 × 106 IU/m2) administered. A rapid decrease in Treg frequency in the circulation was observed at 90 min and at day 1, which was dose dependent (mean decrease 11.6%, SE = 2.3%, range 10.0%-48.2%, n = 37), rebounding at day 2 and increasing to frequencies above baseline over 7 d. Teffs, natural killer cells, and eosinophils also responded, with their frequencies rapidly and dose-dependently decreased in the blood, then returning to, or exceeding, pretreatment levels. Furthermore, there was a dose-dependent down modulation of one of the two signalling subunits of the IL-2 receptor, the β chain (CD122) (mean decrease = 58.0%, SE = 2.8%, range 9.8%-85.5%, n = 33), on Tregs and a reduction in their sensitivity to aldesleukin at 90 min and day 1 and 2 post-treatment. Due to blood volume requirements as well as ethical and practical considerations, the study was limited to adults and to analysis of peripheral blood only. CONCLUSIONS: The DILT1D trial results, most notably the early altered trafficking and desensitisation of Tregs induced by a single ultra-low dose of aldesleukin that resolves within 2-3 d, inform the design of the next trial to determine a repeat dosing regimen aimed at establishing a steady-state Treg frequency increase of 20%-50%, with the eventual goal of preventing T1D. TRIAL REGISTRATION: ISRCTN Registry ISRCTN27852285; ClinicalTrials.gov NCT01827735.

3. Regulatory T Cell Responses in Participants with Type 1 Diabetes after a Single Dose of Interleukin-2: A Non-Randomised, Open Label, Adaptive Dose-Finding Trial

Author

Todd, John A, Evangelou, Marina, Cutler, Antony J, Pekalski, Marcin L, Walker, Neil M, Stevens, Helen E, Porter, Linsey, Smyth, Deborah J, Rainbow, Daniel B, Ferreira, Ricardo C, Esposito, Laura, Hunter, Kara MD, Loudon, Kevin, Irons, Kathryn, Yang, Jennie H, Bell, Charles JM, Schuilenburg, Helen, Heywood, James, Challis, Ben, Neupane, Sankalpa, Clarke, Pamela, Coleman, Gillian, Dawson, Sarah, Goymer, Donna, Anselmiova, Katerina, Kennet, Jane, Brown, Judy, Caddy, Sarah, Lu, Jia, Greatorex, Jane, Goodfellow, Ian Gordon, Wallace, Chris, Tree, Tim I, Evans, Mark, Mander, Adrian Paul, Bond, Simon, Wicker, Linda S, and Waldron-Lynch, Frank

Subjects

lymphocytes, blood counts, blood, memory T cells, T cells, eosinophils, regulatory T cells, 3. Good health, blood plasma

Abstract

BACKGROUND: Interleukin-2 (IL-2) has an essential role in the expansion and function of CD4+ regulatory T cells (Tregs). Tregs reduce tissue damage by limiting the immune response following infection and regulate autoreactive CD4+ effector T cells (Teffs) to prevent autoimmune diseases, such as type 1 diabetes (T1D). Genetic susceptibility to T1D causes alterations in the IL-2 pathway, a finding that supports Tregs as a cellular therapeutic target. Aldesleukin (Proleukin; recombinant human IL-2), which is administered at high doses to activate the immune system in cancer immunotherapy, is now being repositioned to treat inflammatory and autoimmune disorders at lower doses by targeting Tregs. METHODS AND FINDINGS: To define the aldesleukin dose response for Tregs and to find doses that increase Tregs physiologically for treatment of T1D, a statistical and systematic approach was taken by analysing the pharmacokinetics and pharmacodynamics of single doses of subcutaneous aldesleukin in the Adaptive Study of IL-2 Dose on Regulatory T Cells in Type 1 Diabetes (DILT1D), a single centre, non-randomised, open label, adaptive dose-finding trial with 40 adult participants with recently diagnosed T1D. The primary endpoint was the maximum percentage increase in Tregs (defined as CD3+CD4+CD25highCD127low) from the baseline frequency in each participant measured over the 7 d following treatment. There was an initial learning phase with five pairs of participants, each pair receiving one of five pre-assigned single doses from 0.04 × 106 to 1.5 × 106 IU/m2, in order to model the dose-response curve. Results from each participant were then incorporated into interim statistical modelling to target the two doses most likely to induce 10% and 20% increases in Treg frequencies. Primary analysis of the evaluable population (n = 39) found that the optimal doses of aldesleukin to induce 10% and 20% increases in Tregs were 0.101 × 106 IU/m2 (standard error [SE] = 0.078, 95% CI = -0.052, 0.254) and 0.497 × 106 IU/m2 (SE = 0.092, 95% CI = 0.316, 0.678), respectively. On analysis of secondary outcomes, using a highly sensitive IL-2 assay, the observed plasma concentrations of the drug at 90 min exceeded the hypothetical Treg-specific therapeutic window determined in vitro (0.015-0.24 IU/ml), even at the lowest doses (0.040 × 106 and 0.045 × 106 IU/m2) administered. A rapid decrease in Treg frequency in the circulation was observed at 90 min and at day 1, which was dose dependent (mean decrease 11.6%, SE = 2.3%, range 10.0%-48.2%, n = 37), rebounding at day 2 and increasing to frequencies above baseline over 7 d. Teffs, natural killer cells, and eosinophils also responded, with their frequencies rapidly and dose-dependently decreased in the blood, then returning to, or exceeding, pretreatment levels. Furthermore, there was a dose-dependent down modulation of one of the two signalling subunits of the IL-2 receptor, the β chain (CD122) (mean decrease = 58.0%, SE = 2.8%, range 9.8%-85.5%, n = 33), on Tregs and a reduction in their sensitivity to aldesleukin at 90 min and day 1 and 2 post-treatment. Due to blood volume requirements as well as ethical and practical considerations, the study was limited to adults and to analysis of peripheral blood only. CONCLUSIONS: The DILT1D trial results, most notably the early altered trafficking and desensitisation of Tregs induced by a single ultra-low dose of aldesleukin that resolves within 2-3 d, inform the design of the next trial to determine a repeat dosing regimen aimed at establishing a steady-state Treg frequency increase of 20%-50%, with the eventual goal of preventing T1D. TRIAL REGISTRATION: ISRCTN Registry ISRCTN27852285; ClinicalTrials.gov NCT01827735., This is the final version of the article. It first appeared from the Public Library of Science via http://dx.doi.org/10.1371/journal.pmed.1002139

4. Spatiotemporal immune zonation of the human kidney

Author

Dorin-Mirel Popescu, Steven Lisgo, Nathan Richoz, Grace Collord, Anne Y. Warren, James Nicholson, Sarah J. Farndon, Andrew Filby, Roser Vento-Tormo, Marc Bajénoff, Tevita Aho, Gordon L. Frazer, Kevin W. Loudon, Rachel A. Botting, Matthew D. Young, Joy Ursula Lauren Staniforth, Grant D. Stewart, Martin Del Castillo Velasco-Herrera, Benjamin J. Stewart, Stephen Farrell, Nicholas Coleman, Charlotte Guzzo, James N. Armitage, Menna R. Clatworthy, Emily Stephenson, Johanna Burge, Felipe A. Vieira Braga, Muzlifah Haniffa, Imran Mushtaq, Neil J. Sebire, Thomas J. Mitchell, Kile Green, Susan Lindsay, Lira Mamanova, Krzysztof Polanski, Sam Behjati, Alex Cagan, Alexandra M. Riding, Antony C. P. Riddick, John R. Ferdinand, Dyanne Rampling, Sarah A. Teichmann, Mirjana Efremova, Defence Science and Technology Organisation (DSTO), Australian Government, Great Ormond Street Hospital for Children [London] (GOSH), Newcastle University [Newcastle], Institute of Genetic Medicine, Centre d'Immunologie de Marseille - Luminy (CIML), Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)-Aix Marseille Université (AMU), Department of Histopathology & Pediatric Laboratory Medicine, Great Ormond Street Hospital, Institute of Cellular Medicine [Newcastle], Stewart, Benjamin J [0000-0003-4522-0085], Ferdinand, John R [0000-0003-0936-0128], Young, Matthew D [0000-0003-0937-5290], Mitchell, Thomas J [0000-0003-0761-9503], Loudon, Kevin W [0000-0001-9055-6894], Riding, Alexandra M [0000-0002-6915-5671], Staniforth, Joy UL [0000-0003-2817-0098], Vieira Braga, Felipe A [0000-0003-0206-9258], Botting, Rachel A [0000-0001-9595-4605], Stephenson, Emily [0000-0002-4244-4019], Cagan, Alex [0000-0002-7857-4771], Farndon, Sarah J [0000-0001-6024-4267], Polanski, Krzysztof [0000-0002-2586-9576], Del Castillo Velasco-Herrera, Martin [0000-0001-5956-0211], Guzzo, Charlotte [0000-0003-3742-5961], Collord, Grace [0000-0003-1924-4411], Mamanova, Lira [0000-0003-1463-8622], Aho, Tevita [0000-0001-8456-9285], Mushtaq, Imran [0000-0002-7930-0342], Lisgo, Steven [0000-0001-5186-3971], Lindsay, Susan [0000-0003-2980-4582], Stewart, Grant D [0000-0003-3188-9140], Haniffa, Muzlifah [0000-0002-3927-2084], Teichmann, Sarah A [0000-0002-6294-6366], Behjati, Sam [0000-0002-6600-7665], Clatworthy, Menna R [0000-0002-3340-9828], Apollo - University of Cambridge Repository, and Aix Marseille Université (AMU)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)

Subjects

Adult, Myeloid, Neutrophils, Transgene, Mice, Transgenic, Biology, Kidney, [SDV.IMM.II]Life Sciences [q-bio]/Immunology/Innate immunity, Article, 03 medical and health sciences, 0302 clinical medicine, Immune system, Fetus, Single-cell analysis, medicine, Animals, Humans, Myeloid Cells, Lymphocytes, RNA-Seq, 030304 developmental biology, Regulation of gene expression, 0303 health sciences, Multidisciplinary, Macrophages, Gene Expression Regulation, Developmental, Epithelial Cells, biochemical phenomena, metabolism, and nutrition, Epithelium, 3. Good health, Cell biology, Mice, Inbred C57BL, medicine.anatomical_structure, Urinary Tract Infections, bacteria, Female, Single-Cell Analysis, 030217 neurology & neurosurgery, Homeostasis

Abstract

Immune landscape of the human kidney Single-cell RNA sequencing has begun to shed light on the full cellular diversity of specific organs. However, these studies rarely examine organ-specific immune cells. Stewart et al. sequenced healthy adult and fetal kidney samples at a single-cell level to define the heterogeneity in epithelial, myeloid, and lymphoid cells. From this dataset, they identified zonation of cells, with relevance to disease and the varied perturbations that occur in different tumor settings. This profiling of the human kidney generates a comprehensive census of existing cell populations that will help inform the diagnosis and treatment of kidney-related diseases. Science , this issue p. 1461

Published

2018