Your search keyword '"Manikhandan, Mudaliar"' showing total 3 results

1. Changes in Plasma Itaconate Elevation in Early Rheumatoid Arthritis Patients Elucidates Disease Activity Associated Macrophage Activation

Author

Rónán Daly, Gavin Blackburn, Cameron Best, Carl S. Goodyear, Manikhandan Mudaliar, Karl Burgess, Anne Stirling, Duncan Porter, Iain B. McInnes, Michael P. Barrett, and James Dale

Subjects

rheumatoid arthritis, DMARD, macrophage, itaconate, inflammation, liquid chromatography–mass spectrometry (LC-MS), Microbiology, QR1-502

Abstract

Changes in the plasma metabolic profile were characterised in newly diagnosed rheumatoid arthritis (RA) patients upon commencement of conventional disease-modifying anti-rheumatic drug (cDMARD) therapy. Plasma samples collected in an early RA randomised strategy study (NCT00920478) that compared clinical (DAS) disease activity assessment with musculoskeletal ultrasound assessment (MSUS) to drive treatment decisions were subjected to untargeted metabolomic analysis. Metabolic profiles were collected at pre- and three months post-commencement of nonbiologic cDMARD. Metabolites that changed in association with changes in the DAS44 score were identified at the three-month timepoint. A total of nine metabolites exhibited a clear correlation with a reduction in DAS44 score following cDMARD commencement, particularly itaconate, its derived anhydride and a derivative of itaconate CoA. Increasing itaconate correlated with improved DAS44 score and decreasing levels of C-reactive protein (CRP). cDMARD treatment effects invoke consistent changes in plasma detectable metabolites, that in turn implicate clinical disease activity with macrophages. Such changes inform RA pathogenesis and reveal for the first time a link between itaconate production and resolution of inflammatory disease in humans. Quantitative metabolic biomarker-based tests of clinical change in state are feasible and should be developed around the itaconate pathway.

Published

2020

2. Sterol 14α-demethylase mutation leads to amphotericin B resistance in Leishmania mexicana.

Author

Roy Mwenechanya, Julie Kovářová, Nicholas J Dickens, Manikhandan Mudaliar, Pawel Herzyk, Isabel M Vincent, Stefan K Weidt, Karl E Burgess, Richard J S Burchmore, Andrew W Pountain, Terry K Smith, Darren J Creek, Dong-Hyun Kim, Galina I Lepesheva, and Michael P Barrett

Subjects

Arctic medicine. Tropical medicine, RC955-962, Public aspects of medicine, RA1-1270

Abstract

Amphotericin B has emerged as the therapy of choice for use against the leishmaniases. Administration of the drug in its liposomal formulation as a single injection is being promoted in a campaign to bring the leishmaniases under control. Understanding the risks and mechanisms of resistance is therefore of great importance. Here we select amphotericin B-resistant Leishmania mexicana parasites with relative ease. Metabolomic analysis demonstrated that ergosterol, the sterol known to bind the drug, is prevalent in wild-type cells, but diminished in the resistant line, where alternative sterols become prevalent. This indicates that the resistance phenotype is related to loss of drug binding. Comparing sequences of the parasites' genomes revealed a plethora of single nucleotide polymorphisms that distinguish wild-type and resistant cells, but only one of these was found to be homozygous and associated with a gene encoding an enzyme in the sterol biosynthetic pathway, sterol 14α-demethylase (CYP51). The mutation, N176I, is found outside of the enzyme's active site, consistent with the fact that the resistant line continues to produce the enzyme's product. Expression of wild-type sterol 14α-demethylase in the resistant cells caused reversion to drug sensitivity and a restoration of ergosterol synthesis, showing that the mutation is indeed responsible for resistance. The amphotericin B resistant parasites become hypersensitive to pentamidine and also agents that induce oxidative stress. This work reveals the power of combining polyomics approaches, to discover the mechanism underlying drug resistance as well as offering novel insights into the selection of resistance to amphotericin B itself.

Published

2017

3. Sterol 14α-demethylase mutation leads to amphotericin B resistance in Leishmania mexicana.

Author

Mwenechanya, Roy, Kovářová, Julie, Dickens, Nicholas J., Manikhandan, Mudaliar, Herzyk, Pawel, Vincent, Isabel M., Weidt, Stefan K., Burgess, Karl E., Burchmore, Richard J. S., Pountain, Andrew W., Smith, Terry K., Creek, Darren J., Kim, Dong-Hyun, Lepesheva, Galina I., and Barrett, Michael P.

Subjects

DEMETHYLASE, AMPHOTERICIN B, LEISHMANIA mexicana, GENETIC mutation, STEROLS

Abstract

Amphotericin B has emerged as the therapy of choice for use against the leishmaniases. Administration of the drug in its liposomal formulation as a single injection is being promoted in a campaign to bring the leishmaniases under control. Understanding the risks and mechanisms of resistance is therefore of great importance. Here we select amphotericin B-resistant Leishmania mexicana parasites with relative ease. Metabolomic analysis demonstrated that ergosterol, the sterol known to bind the drug, is prevalent in wild-type cells, but diminished in the resistant line, where alternative sterols become prevalent. This indicates that the resistance phenotype is related to loss of drug binding. Comparing sequences of the parasites’ genomes revealed a plethora of single nucleotide polymorphisms that distinguish wild-type and resistant cells, but only one of these was found to be homozygous and associated with a gene encoding an enzyme in the sterol biosynthetic pathway, sterol 14α-demethylase (CYP51). The mutation, N176I, is found outside of the enzyme’s active site, consistent with the fact that the resistant line continues to produce the enzyme’s product. Expression of wild-type sterol 14α-demethylase in the resistant cells caused reversion to drug sensitivity and a restoration of ergosterol synthesis, showing that the mutation is indeed responsible for resistance. The amphotericin B resistant parasites become hypersensitive to pentamidine and also agents that induce oxidative stress. This work reveals the power of combining polyomics approaches, to discover the mechanism underlying drug resistance as well as offering novel insights into the selection of resistance to amphotericin B itself. [ABSTRACT FROM AUTHOR]

Published

2017