Your search keyword '"Darren J. Creek"' showing total 321 results

201. Integrated metabolomic and transcriptomic analyses of the synergistic effect of polymyxin–rifampicin combination against Pseudomonas aeruginosa.

Author

Mahamad Maifiah, Mohd Hafidz, Zhu, Yan, Tsuji, Brian T., Creek, Darren J., Velkov, Tony, and Li, Jian

Subjects

PSEUDOMONAS aeruginosa, POLYMYXIN B, LIQUID chromatography-mass spectrometry, METABOLOMICS, BACTERIAL cell walls

Abstract

Background: Understanding the mechanism of antimicrobial action is critical for improving antibiotic therapy. For the first time, we integrated correlative metabolomics and transcriptomics of Pseudomonas aeruginosa to elucidate the mechanism of synergistic killing of polymyxin–rifampicin combination. Methods: Liquid chromatography-mass spectrometry and RNA-seq analyses were conducted to identify the significant changes in the metabolome and transcriptome of P. aeruginosa PAO1 after exposure to polymyxin B (1 mg/L) and rifampicin (2 mg/L) alone, or in combination over 24 h. A genome-scale metabolic network was employed for integrative analysis. Results: In the first 4-h treatment, polymyxin B monotherapy induced significant lipid perturbations, predominantly to fatty acids and glycerophospholipids, indicating a substantial disorganization of the bacterial outer membrane. Expression of ParRS, a two-component regulatory system involved in polymyxin resistance, was increased by polymyxin B alone. Rifampicin alone caused marginal metabolic perturbations but significantly affected gene expression at 24 h. The combination decreased the gene expression of quorum sensing regulated virulence factors at 1 h (e.g. key genes involved in phenazine biosynthesis, secretion system and biofilm formation); and increased the expression of peptidoglycan biosynthesis genes at 4 h. Notably, the combination caused substantial accumulation of nucleotides and amino acids that last at least 4 h, indicating that bacterial cells were in a state of metabolic arrest. Conclusion: This study underscores the substantial potential of integrative systems pharmacology to determine mechanisms of synergistic bacterial killing by antibiotic combinations, which will help optimize their use in patients. [ABSTRACT FROM AUTHOR]

Published

2022

202. Systematic Down-Selection of Repurposed Drug Candidates for COVID-19.

Author

MacRaild, Christopher A., Mohammed, Muzaffar-Ur-Rehman, Faheem, Murugesan, Sankaranarayanan, Styles, Ian K., Peterson, Amanda L., Kirkpatrick, Carl M. J., Cooper, Matthew A., Palombo, Enzo A., Simpson, Moana M., Jain, Hardik A., Agarwal, Vinti, McAuley, Alexander J., Kumar, Anupama, Creek, Darren J., Trevaskis, Natalie L., and Vasan, Seshadri S.

Subjects

POST-acute COVID-19 syndrome, MEDICAL personnel, COVID-19, DRUG efficacy, MEDICAL scientists

Abstract

SARS-CoV-2 is the cause of the COVID-19 pandemic which has claimed more than 6.5 million lives worldwide, devastating the economy and overwhelming healthcare systems globally. The development of new drug molecules and vaccines has played a critical role in managing the pandemic; however, new variants of concern still pose a significant threat as the current vaccines cannot prevent all infections. This situation calls for the collaboration of biomedical scientists and healthcare workers across the world. Repurposing approved drugs is an effective way of fast-tracking new treatments for recently emerged diseases. To this end, we have assembled and curated a database consisting of 7817 compounds from the Compounds Australia Open Drug collection. We developed a set of eight filters based on indicators of efficacy and safety that were applied sequentially to down-select drugs that showed promise for drug repurposing efforts against SARS-CoV-2. Considerable effort was made to evaluate approximately 14,000 assay data points for SARS-CoV-2 FDA/TGA-approved drugs and provide an average activity score for 3539 compounds. The filtering process identified 12 FDA-approved molecules with established safety profiles that have plausible mechanisms for treating COVID-19 disease. The methodology developed in our study provides a template for prioritising drug candidates that can be repurposed for the safe, efficacious, and cost-effective treatment of COVID-19, long COVID, or any other future disease. We present our database in an easy-to-use interactive interface (CoviRx that was also developed to enable the scientific community to access to the data of over 7000 potential drugs and to implement alternative prioritisation and down-selection strategies. [ABSTRACT FROM AUTHOR]

Published

2022

203. Lipidomics profiles in hepatocytes from nonalcoholic steatohepatitis patients differ markedly from in vitro-induced steatotic hepatocytes.

Author

Kralj, Thomas, Khatri, Raju, Brouwer, Kenneth R., Brouwer, Kim L. R., and Creek, Darren J.

Subjects

NON-alcoholic fatty liver disease, LIPIDOMICS

Abstract

Nonalcoholic steatohepatitis (NASH) is a severe form of liver injury that can be caused by a variety of stimuli and has a significant mortality rate. A common technique to induce in vitro steatosis involves culturing primary human hepatocytes (PHH) in fatty acid-enriched media. This study compared the lipidome of PHH cultured in fatty acid-enriched media to hepatocytes from patients with NASH and healthy controls. Hepatocytes from NASH patients displayed increased total cellular abundance of glycerolipids and phospholipids compared to healthy control hepatocytes. PHH cultured in fatty acidenriched media demonstrated increased glycerolipids. However, these culture conditions did not induce elevated phospholipid levels. Thus, culturing PHH in fatty acid-enriched media has limited capacity to emulate the environment of hepatocytes in NASH patients. [ABSTRACT FROM AUTHOR]

Published

2022

204. Chemoresistant Cancer Cell Lines Are Characterized by Migratory, Amino Acid Metabolism, Protein Catabolism and IFN1 Signalling Perturbations.

Author

Acland, Mitchell, Lokman, Noor A., Young, Clifford, Anderson, Dovile, Condina, Mark, Desire, Chris, Noye, Tannith M., Wang, Wanqi, Ricciardelli, Carmela, Creek, Darren J., Oehler, Martin K., Hoffmann, Peter, and Klingler-Hoffmann, Manuela

Subjects

AMINO acid metabolism, PROTEIN metabolism, OVARIAN tumors, CANCER chemotherapy, METABOLISM, CELL motility, INTERFERONS, CELLULAR signal transduction, PROTEOMICS, MOLECULAR biology, MASS spectrometry, CELL lines, DRUG resistance in cancer cells

Abstract

Simple Summary: While chemoresistance remains a major barrier to improving the outcomes for patients with ovarian cancer, the molecular features, and associated biological functions, which underpin chemoresistance in ovarian cancer remain poorly understood. In this study we aimed to provide insight into the proteins and metabolites, and their associated biological pathways, which play a role in conferring chemoresistance to ovarian cancer. Through mass spectrometry analysis comparing the proteome and metabolome of chemosensitive vs chemoresistant ovarian cancer cell lines we revealed numerous perturbations in signalling and metabolic pathways in chemoresistant cells. Further comparison to primary cells taken from patients with chemoresistant or chemosensitive disease identified a shared dysregulation in cytokine and type 1 interferon signalling. Our research sets the foundation for a deeper understanding of the proteomic and metabolomic features of chemoresistance and identifies type 1 interferon signalling as a common feature of chemoresistance. Chemoresistance remains the major barrier to effective ovarian cancer treatment. The molecular features and associated biological functions of this phenotype remain poorly understood. We developed carboplatin-resistant cell line models using OVCAR5 and CaOV3 cell lines with the aim of identifying chemoresistance-specific molecular features. Chemotaxis and CAM invasion assays revealed enhanced migratory and invasive potential in OVCAR5-resistant, compared to parental cell lines. Mass spectrometry analysis was used to analyse the metabolome and proteome of these cell lines, and was able to separate these populations based on their molecular features. It revealed signalling and metabolic perturbations in the chemoresistant cell lines. A comparison with the proteome of patient-derived primary ovarian cancer cells grown in culture showed a shared dysregulation of cytokine and type 1 interferon signalling, potentially revealing a common molecular feature of chemoresistance. A comprehensive analysis of a larger patient cohort, including advanced in vitro and in vivo models, promises to assist with better understanding the molecular mechanisms of chemoresistance and the associated enhancement of migration and invasion. [ABSTRACT FROM AUTHOR]

Published

2022

205. Red Blood Cell BCL-x L Is Required for Plasmodium falciparum Survival: Insights into Host-Directed Malaria Therapies.

Author

Boulet, Coralie, Siddiqui, Ghizal, Gaynor, Taylah L., Doerig, Christian, Creek, Darren J., and Carvalho, Teresa G.

Subjects

MALARIA, ERYTHROCYTES, PLASMODIUM falciparum, DRUG repositioning, WESTERN immunoblotting, DRUG resistance

Abstract

The development of antimalarial drug resistance is an ongoing problem threatening progress towards the elimination of malaria, and antimalarial treatments are urgently needed for drug-resistant malaria infections. Host-directed therapies (HDT) represent an attractive strategy for the development of new antimalarials with untapped targets and low propensity for resistance. In addition, drug repurposing in the context of HDT can lead to a substantial decrease in the time and resources required to develop novel antimalarials. Host BCL-xL is a target in anti-cancer therapy and is essential for the development of numerous intracellular pathogens. We hypothesised that red blood cell (RBC) BCL-xL is essential for Plasmodium development and tested this hypothesis using six BCL-xL inhibitors, including one FDA-approved compound. All BCL-xL inhibitors tested impaired proliferation of Plasmodium falciparum 3D7 parasites in vitro at low micromolar or sub-micromolar concentrations. Western blot analysis of infected cell fractions and immunofluorescence microscopy assays revealed that host BCL-xL is relocated from the RBC cytoplasm to the vicinity of the parasite upon infection. Further, immunoprecipitation of BCL-xL coupled with mass spectrometry analysis identified that BCL-xL forms unique molecular complexes with human μ-calpain in uninfected RBCs, and with human SHOC2 in infected RBCs. These results provide interesting perspectives for the development of host-directed antimalarial therapies and drug repurposing efforts. [ABSTRACT FROM AUTHOR]

Published

2022

206. Cell biological analysis reveals an essential role for Pfcerli2 in erythrocyte invasion by malaria parasites.

Author

Liffner, Benjamin, Balbin, Juan Miguel, Shami, Gerald J., Siddiqui, Ghizal, Strauss, Jan, Frölich, Sonja, Heinemann, Gary K., Edwards, Ella May, Alder, Arne, Wichers, Jan Stephan, Creek, Darren J., Tilley, Leann, Dixon, Matthew W. A., Gilberger, Tim-Wolf, and Wilson, Danny W.

Subjects

PLASMODIUM, CELL analysis, CHROMOSOME duplication, PLASMODIUM falciparum, ANTIGEN processing, MALARIA, ERYTHROCYTES

Abstract

Merozoite invasion of host red blood cells (RBCs) is essential for survival of the human malaria parasite Plasmodium falciparum. Proteins involved with RBC binding and invasion are secreted from dual-club shaped organelles at the apical tip of the merozoite called the rhoptries. Here we characterise P. falciparum Cytosolically Exposed Rhoptry Leaflet Interacting protein 2 (PfCERLI2), as a rhoptry bulb protein that is essential for merozoite invasion. Phylogenetic analyses show that cerli2 arose through an ancestral gene duplication of cerli1. We show that PfCERLI2 is essential for blood-stage growth and localises to the cytosolic face of the rhoptry bulb. Inducible knockdown of PfCERLI2 led to a proportion of merozoites failing to invade and was associated with elongation of the rhoptry organelle during merozoite development and inhibition of rhoptry antigen processing. These findings identify PfCERLI2 as a protein that has key roles in rhoptry biology during merozoite invasion. Benjamin Liffner and Miguel Balbin et al. report that the Plasmodium falciparum protein, PfCERLI2, localises to the cytosolic face of the parasite's rhoptry bulb and is essential for invasion and growth within human red blood cells. [ABSTRACT FROM AUTHOR]

Published

2022

207. The sphingosine 1-phosphate receptor 2/4 antagonist JTE-013 elicits off-target effects on sphingolipid metabolism.

Author

Pitman, Melissa R., Lewis, Alexander C., Davies, Lorena T., Moretti, Paul A. B., Anderson, Dovile, Creek, Darren J., Powell, Jason A., and Pitson, Stuart M.

Subjects

SPHINGOSINE, MYELOID leukemia, SMALL molecules, METABOLISM, G protein coupled receptors, CERAMIDES

Abstract

Sphingosine 1-phosphate (S1P) is a signaling lipid that has broad roles, working either intracellularly through various protein targets, or extracellularly via a family of five G-protein coupled receptors. Agents that selectively and specifically target each of the S1P receptors have been sought as both biological tools and potential therapeutics. JTE-013, a small molecule antagonist of S1P receptors 2 and 4 (S1P2 and S1P4) has been widely used in defining the roles of these receptors in various biological processes. Indeed, our previous studies showed that JTE-013 had anti-acute myeloid leukaemia (AML) activity, supporting a role for S1P2 in the biology and therapeutic targeting of AML. Here we examined this further and describe lipidomic analysis of AML cells that revealed JTE-013 caused alterations in sphingolipid metabolism, increasing cellular ceramides, dihydroceramides, sphingosine and dihydrosphingosine. Further examination of the mechanisms behind these observations showed that JTE-013, at concentrations frequently used in the literature to target S1P2/4, inhibits several sphingolipid metabolic enzymes, including dihydroceramide desaturase 1 and both sphingosine kinases. Collectively, these findings demonstrate that JTE-013 can have broad off-target effects on sphingolipid metabolism and highlight that caution must be employed in interpreting the use of this reagent in defining the roles of S1P2/4. [ABSTRACT FROM AUTHOR]

Published

2022

208. A new mass spectral library for high-coverage and reproducible analysis of the Plasmodium falciparum–infected red blood cell proteome.

Author

Siddiqui, Ghizal, De Paoli, Amanda, MacRaild, Christopher A, Sexton, Anna E, Boulet, Coralie, Shah, Anup D, Batty, Mitchell B, Schittenhelm, Ralf B, Carvalho, Teresa G, and Creek, Darren J

Subjects

ERYTHROCYTES, ERYTHROCYTE membranes, PLASMODIUM, PLASMODIUM falciparum, PROTEOMICS, DRUG resistance

Abstract

Background Plasmodium falciparum causes the majority of malaria mortality worldwide, and the disease occurs during the asexual red blood cell (RBC) stage of infection. In the absence of an effective and available vaccine, and with increasing drug resistance, asexual RBC stage parasites are an important research focus. In recent years, mass spectrometry–based proteomics using data-dependent acquisition has been extensively used to understand the biochemical processes within the parasite. However, data-dependent acquisition is problematic for the detection of low-abundance proteins and proteome coverage and has poor run-to-run reproducibility. Results Here, we present a comprehensive P. falciparum –infected RBC (iRBC) spectral library to measure the abundance of 44,449 peptides from 3,113 P. falciparum and 1,617 RBC proteins using a data-independent acquisition mass spectrometric approach. The spectral library includes proteins expressed in the 3 morphologically distinct RBC stages (ring, trophozoite, schizont), the RBC compartment of trophozoite-iRBCs, and the cytosolic fraction from uninfected RBCs. This spectral library contains 87% of all P. falciparum proteins that have previously been reported with protein-level evidence in blood stages, as well as 692 previously unidentified proteins. The P. falciparum spectral library was successfully applied to generate semi-quantitative proteomics datasets that characterize the 3 distinct asexual parasite stages in RBCs, and compared artemisinin-resistant (Cam3.IIR539T) and artemisinin-sensitive (Cam3.IIrev) parasites. Conclusion A reproducible, high-coverage proteomics spectral library and analysis method has been generated for investigating sets of proteins expressed in the iRBC stage of P. falciparum malaria. This will provide a foundation for an improved understanding of parasite biology, pathogenesis, drug mechanisms, and vaccine candidate discovery for malaria. [ABSTRACT FROM AUTHOR]

Published

2022

209. Analytical and Omics-Based Advances in the Study of Drug-Induced Liver Injury.

Author

Kralj, Thomas, Brouwer, Kim L R, and Creek, Darren J

Subjects

DRUG side effects, LIVER injuries, DRUG development, METABOLOMICS, GENE expression, PROTEOMICS

Abstract

Drug-induced liver injury (DILI) is a significant clinical issue, affecting 1–1.5 million patients annually, and remains a major challenge during drug development—toxicity and safety concerns are the second-highest reason for drug candidate failure. The future prevalence of DILI can be minimized by developing a greater understanding of the biological mechanisms behind DILI. Both qualitative and quantitative analytical techniques are vital to characterizing and investigating DILI. In vitro assays are capable of characterizing specific aspects of a drug's hepatotoxic nature and multiplexed assays are capable of characterizing and scoring a drug's association with DILI. However, an even deeper insight into the perturbations to biological pathways involved in the mechanisms of DILI can be gained through the use of omics-based analytical techniques: genomics, transcriptomics, proteomics, and metabolomics. These omics analytical techniques can offer qualitative and quantitative insight into genetic susceptibilities to DILI, the impact of drug treatment on gene expression, and the effect on protein and metabolite abundance. This review will discuss the analytical techniques that can be applied to characterize and investigate the biological mechanisms of DILI and potential predictive biomarkers. [ABSTRACT FROM AUTHOR]

Published

2021

210. Genetic and pharmacological evidence for kinetic competition between alternative poly(A) sites in yeast.

Author

Turner, Rachael Emily, Harrison, Paul F., Swaminathan, Angavai, Kraupner-Taylor, Calvin A., Goldie, Belinda J., See, Michael, Peterson, Amanda L., Schittenhelm, Ralf B., Powell, David R., Creek, Darren J., Dichtl, Bernhard, and Beilharz, Traude H.

Published

2021

211. Altered metabolic pathways in a transgenic mouse model suggest mechanistic role of amyloid precursor protein overexpression in Alzheimer's disease.

Author

Dejakaisaya, Hattapark, Harutyunyan, Anna, Kwan, Patrick, and Jones, Nigel C.

Subjects

PROTEIN overexpression, AMYLOID beta-protein precursor, LABORATORY mice, ALZHEIMER'S disease, TRANSGENIC mice, LIQUID chromatography-mass spectrometry, LIPID metabolism

Abstract

Introduction: The mechanistic role of amyloid precursor protein (APP) in Alzheimer's disease (AD) remains unclear. Objectives: Here, we aimed to identify alterations in cerebral metabolites and metabolic pathways in cortex, hippocampus and serum samples from Tg2576 mice, a widely used mouse model of AD. Methods: Metabolomic profilings using liquid chromatography-mass spectrometry were performed and analysed with MetaboAnalyst and weighted correlation network analysis (WGCNA). Results: Expressions of 11 metabolites in cortex, including hydroxyphenyllactate—linked to oxidative stress—and phosphatidylserine—lipid metabolism—were significantly different between Tg2576 and WT mice (false discovery rate < 0.05). Four metabolic pathways from cortex, including glycerophospholipid metabolism and pyrimidine metabolism, and one pathway (sulphur metabolism) from hippocampus, were significantly enriched in Tg2576 mice. Network analysis identified five pathways, including alanine, aspartate and glutamate metabolism, and mitochondria electron transport chain, that were significantly correlated with AD genotype. Conclusions: Changes in metabolite concentrations and metabolic pathways are present in the early stage of APP pathology, and may be important for AD development and progression. [ABSTRACT FROM AUTHOR]

Published

2021

212. Non‐canonical metabolic pathways in the malaria parasite detected by isotope‐tracing metabolomics.

Author

Cobbold, Simon A, V Tutor, Madel, Frasse, Philip, McHugh, Emma, Karnthaler, Markus, Creek, Darren J, Odom John, Audrey, Tilley, Leann, Ralph, Stuart A, and McConville, Malcolm J

Subjects

PLASMODIUM, METABOLOMICS, ERYTHROCYTES, MASS spectrometry, ESSENTIAL nutrients, METABOLITES

Abstract

The malaria parasite, Plasmodiumfalciparum, proliferates rapidly in human erythrocytes by actively scavenging multiple carbon sources and essential nutrients from its host cell. However, a global overview of the metabolic capacity of intraerythrocytic stages is missing. Using multiplex 13C‐labelling coupled with untargeted mass spectrometry and unsupervised isotopologue grouping, we have generated a draft metabolome of P.falciparum and its host erythrocyte consisting of 911 and 577 metabolites, respectively, corresponding to 41% of metabolites and over 70% of the metabolic reaction predicted from the parasite genome. An additional 89 metabolites and 92 reactions were identified that were not predicted from genomic reconstructions, with the largest group being associated with metabolite damage‐repair systems. Validation of the draft metabolome revealed four previously uncharacterised enzymes which impact isoprenoid biosynthesis, lipid homeostasis and mitochondrial metabolism and are necessary for parasite development and proliferation. This study defines the metabolic fate of multiple carbon sources in P.falciparum, and highlights the activity of metabolite repair pathways in these rapidly growing parasite stages, opening new avenues for drug discovery. Synopsis: Multiplex stable‐isotope labelling defines the observable metabolome of red blood cell stages of the malaria parasite Plasmodiumfalciparum and indicates potential roles for metabolic enzymes of unknown function. A draft metabolome of P.falciparum and its host erythrocyte is presented, consisting of 911 and 577 metabolites respectively.The metabolome covers 70% of predicted metabolic reactions.92 unpredicted reactions are identified, the largest group associated with metabolite damage repair.Mediators of isoprenoid biosynthesis, lipid homeostasis, and mitochondrial metabolism are identified. [ABSTRACT FROM AUTHOR]

Published

2021

213. Acinetobacter baumannii: Polymyxins Bind to the Cell Surface of Unculturable Acinetobacter baumannii and Cause Unique Dependent Resistance (Adv. Sci. 15/2020).

Author

Zhu, Yan, Lu, Jing, Han, Mei‐Ling, Jiang, Xukai, Azad, Mohammad A. K., Patil, Nitin A., Lin, Yu‐Wei, Zhao, Jinxin, Hu, Yang, Yu, Heidi H., Chen, Ke, Boyce, John D., Dunstan, Rhys A., Lithgow, Trevor, Barlow, Christopher K., Li, Weifeng, Schneider‐Futschik, Elena K., Wang, Jiping, Gong, Bin, and Sommer, Bjorn

Subjects

ACINETOBACTER baumannii, CELL membranes, POLYMYXIN B, AGAR plates

Published

2020

214. New Drug Research Findings from Monash University Discussed (The Immune Response To Rna Suppresses Nucleic Acid Synthesis By Limiting Ribose 5-phosphate).

Subjects

NUCLEIC acids, RIBOSE, IMMUNE response, RNA, POLY ADP ribose, PENTOSE phosphate pathway

Abstract

A recent study conducted by researchers at Monash University in Clayton, Australia, has found that the immune response to RNA can suppress nucleic acid synthesis by limiting the production of ribose 5-phosphate. The study focused on the antiviral effector Protein Kinase RNA-activated (PKR), which was found to control the generation of ribose 5-phosphate by phosphorylating and inhibiting the Ribose 5-Phosphate Isomerase A (RPIA). This discovery suggests that targeting RPIA could be a potential innovative antiviral treatment. The study also found that targeting the pentose phosphate pathway (PPP) during infection can decrease the replication of the Herpes simplex virus. [Extracted from the article]

Published

2024

215. Investigators from Monash University Release New Data on Nanoparticles [Influence of Chirality On Protein Corona Formation of Low-fouling Chiral Poly(2-oxazoline) Coated Nanoparticles].

Subjects

CHIRALITY, LIQUID chromatography-mass spectrometry, NANOPARTICLES, DATA release

Abstract

Researchers from Monash University in Parkville, Australia have conducted a study on the influence of chirality on the formation of protein corona around low-fouling chiral poly(2-oxazoline) coated nanoparticles. The study found that the chirality of the hydrophilic polymer can affect the composition of the corona, with differences in protein population abundances observed between enantiomers. The researchers suggest that this insight can inform the future design of chiral poly(2-oxazoline) nanotherapeutics. The study was published in the European Polymer Journal and was funded by various Australian research organizations. [Extracted from the article]

Published

2024

216. Lipid A profiling and metabolomics analysis of paired polymyxin-susceptible and -resistant MDR Klebsiella pneumoniae clinical isolates from the same patients before and after colistin treatment.

Author

Aye, Su Mon, Galani, Irene, Han, Mei-Ling, Karaiskos, Ilias, Creek, Darren J, Zhu, Yan, Lin, Yu-Wei, Velkov, Tony, Giamarellou, Helen, and Li, Jian

Subjects

POLYMYXIN B, KLEBSIELLA pneumoniae, KREBS cycle, PENTOSE phosphate pathway, LIPIDS, COLISTIN, CARBON metabolism, LIPID metabolism, ANTIBIOTICS, KLEBSIELLA, BIOCHEMISTRY, RESEARCH, RESEARCH methodology, MEDICAL cooperation, EVALUATION research, KLEBSIELLA infections, COMPARATIVE studies, POLYMYXIN, RESEARCH funding, DRUG resistance in microorganisms, MICROBIAL sensitivity tests, PHARMACODYNAMICS

Abstract

Background: The increased incidence of polymyxin-resistant MDR Klebsiella pneumoniae has become a major global health concern.Objectives: To characterize the lipid A profiles and metabolome differences between paired polymyxin-susceptible and -resistant MDR K. pneumoniae clinical isolates.Methods: Three pairs of K. pneumoniae clinical isolates from the same patients were examined [ATH 7 (polymyxin B MIC 0.25 mg/L) versus ATH 8 (64 mg/L); ATH 15 (0.5 mg/L) versus ATH 16 (32 mg/L); and ATH 17 (0.5 mg/L) versus ATH 18 (64 mg/L)]. Lipid A and metabolomes were analysed using LC-MS and bioinformatic analysis was conducted.Results: The predominant species of lipid A in all three paired isolates were hexa-acylated and 4-amino-4-deoxy-l-arabinose-modified lipid A species were detected in the three polymyxin-resistant isolates. Significant metabolic differences were evident between the paired isolates. Compared with their corresponding polymyxin-susceptible isolates, the levels of metabolites in amino sugar metabolism (UDP-N-acetyl-α-d-glucosamine and UDP-N-α-acetyl-d-mannosaminuronate) and central carbon metabolism (e.g. pentose phosphate pathway and tricarboxylic acid cycle) were significantly reduced in all polymyxin-resistant isolates [fold change (FC) > 1.5, P < 0.05]. Similarly, nucleotides, amino acids and key metabolites in glycerophospholipid metabolism, namely sn-glycerol-3-phosphate and sn-glycero-3-phosphoethanolamine, were significantly reduced across all polymyxin-resistant isolates (FC > 1.5, P < 0.05) compared with polymyxin-susceptible isolates. However, higher glycerophospholipid levels were evident in polymyxin-resistant ATH 8 and ATH 16 (FC > 1.5, P < 0.05) compared with their corresponding susceptible isolates.Conclusions: To our knowledge, this study is the first to reveal significant metabolic perturbations associated with polymyxin resistance in K. pneumoniae. [ABSTRACT FROM AUTHOR]

Published

2020

217. Polymyxins Bind to the Cell Surface of Unculturable Acinetobacter baumannii and Cause Unique Dependent Resistance.

Author

Zhu, Yan, Lu, Jing, Han, Mei‐Ling, Jiang, Xukai, Azad, Mohammad A. K., Patil, Nitin A., Lin, Yu‐Wei, Zhao, Jinxin, Hu, Yang, Yu, Heidi H., Chen, Ke, Boyce, John D., Dunstan, Rhys A., Lithgow, Trevor, Barlow, Christopher K., Li, Weifeng, Schneider‐Futschik, Elena K., Wang, Jiping, Gong, Bin, and Sommer, Bjorn

Subjects

POLYMYXIN B, ACINETOBACTER baumannii, REACTIVE oxygen species, CELL membranes, AMINO acid sequence, DRUG resistance in bacteria

Abstract

Multidrug‐resistant Acinetobacter baumannii is a top‐priority pathogen globally and polymyxins are a last‐line therapy. Polymyxin dependence in A. baumannii (i.e., nonculturable on agar without polymyxins) is a unique and highly‐resistant phenotype with a significant potential to cause treatment failure in patients. The present study discovers that a polymyxin‐dependent A. baumannii strain possesses mutations in both lpxC (lipopolysaccharide biosynthesis) and katG (reactive oxygen species scavenging) genes. Correlative multiomics analyses show a significantly remodeled cell envelope and remarkably abundant phosphatidylglycerol in the outer membrane (OM). Molecular dynamics simulations and quantitative membrane lipidomics reveal that polymyxin‐dependent growth emerges only when the lipopolysaccharide‐deficient OM distinctively remodels with ≥ 35% phosphatidylglycerol, and with "patch" binding on the OM by the rigid polymyxin molecules containing strong intramolecular hydrogen bonding. Rather than damaging the OM, polymyxins bind to the phosphatidylglycerol‐rich OM and strengthen the membrane integrity, thereby protecting bacteria from external reactive oxygen species. Dependent growth is observed exclusively with polymyxin analogues, indicating a critical role of the specific amino acid sequence of polymyxins in forming unique structures for patch‐binding to bacterial OM. Polymyxin dependence is a novel antibiotic resistance mechanism and the current findings highlight the risk of 'invisible' polymyxin‐dependent isolates in the evolution of resistance. [ABSTRACT FROM AUTHOR]

Published

2020

218. Sulfoxide‐Containing Polymer‐Coated Nanoparticles Demonstrate Minimal Protein Fouling and Improved Blood Circulation.

Author

Qiao, Ruirui, Fu, Changkui, Li, Yuhuan, Qi, Xiaole, Ni, Dalong, Nandakumar, Aparna, Siddiqui, Ghizal, Wang, Haiyan, Zhang, Zheng, Wu, Tingting, Zhong, Jian, Tang, Shi‐Yang, Pan, Shuaijun, Zhang, Cheng, Whittaker, Michael R., Engle, Jonathan W., Creek, Darren J., Caruso, Frank, Ke, Pu Chun, and Cai, Weibo

Subjects

BLOOD circulation, IRON oxide nanoparticles, POLYMERSOMES, FOULING, HYDROPHILIC surfaces, ETHYL acrylate

Abstract

Minimizing the interaction of nanomedicines with the mononuclear phagocytic system (MPS) is a critical challenge for their clinical translation. Conjugating polyethylene glycol (PEG) to nanomedicines is regarded as an effective approach to reducing the sequestration of nanomedicines by the MPS. However, recent concerns about the immunogenicity of PEG highlight the demand of alternative low‐fouling polymers as innovative coating materials for nanoparticles. Herein, a highly hydrophilic sulfoxide‐containing polymer—poly(2‐(methylsulfinyl)ethyl acrylate) (PMSEA)—is used for the surface coating of iron oxide nanoparticles (IONPs). It is found that the PMSEA polymer coated IONPs have a more hydrophilic surface than their PEGylated counterparts, and demonstrate remarkably reduced macrophage cellular uptake and much less association with human plasma proteins. In vivo study of biodistribution and pharmacokinetics further reveals a much‐extended blood circulation (≈2.5 times longer in terms of elimination half‐life t1/2) and reduced accumulation (approximately two times less) in the organs such as the liver and spleen for IONPs coated by PMSEA than those by PEG. It is envisaged that the highly hydrophilic sulfoxide‐containing polymers have huge potential to be employed as an advantageous alternative to PEG for the surface functionalization of a variety of nanoparticles for long circulation and improved delivery. [ABSTRACT FROM AUTHOR]

Published

2020

219. System-wide biochemical analysis reveals ozonide antimalarials initially act by disrupting Plasmodium falciparum haemoglobin digestion.

Author

Giannangelo, Carlo, Siddiqui, Ghizal, De Paoli, Amanda, Anderson, Bethany M., Edgington-Mitchell, Laura E., Charman, Susan A., and Creek, Darren J.

Subjects

PROTEASOMES, PROTEOLYSIS, PLASMODIUM falciparum, ANTIMALARIALS, ERYTHROCYTES, HEMOGLOBINS, PLASMODIUM

Abstract

Ozonide antimalarials, OZ277 (arterolane) and OZ439 (artefenomel), are synthetic peroxide-based antimalarials with potent activity against the deadliest malaria parasite, Plasmodium falciparum. Here we used a "multi-omics" workflow, in combination with activity-based protein profiling (ABPP), to demonstrate that peroxide antimalarials initially target the haemoglobin (Hb) digestion pathway to kill malaria parasites. Time-dependent metabolomic profiling of ozonide-treated P. falciparum infected red blood cells revealed a rapid depletion of short Hb-derived peptides followed by subsequent alterations in lipid and nucleotide metabolism, while untargeted peptidomics showed accumulation of longer Hb-derived peptides. Quantitative proteomics and ABPP assays demonstrated that Hb-digesting proteases were increased in abundance and activity following treatment, respectively. Ozonide-induced depletion of short Hb-derived peptides was less extensive in a drug-treated K13-mutant artemisinin resistant parasite line (Cam3.IIR539T) than in the drug-treated isogenic sensitive strain (Cam3.IIrev), further confirming the association between ozonide activity and Hb catabolism. To demonstrate that compromised Hb catabolism may be a primary mechanism involved in ozonide antimalarial activity, we showed that parasites forced to rely solely on Hb digestion for amino acids became hypersensitive to short ozonide exposures. Quantitative proteomics analysis also revealed parasite proteins involved in translation and the ubiquitin-proteasome system were enriched following drug treatment, suggestive of the parasite engaging a stress response to mitigate ozonide-induced damage. Taken together, these data point to a mechanism of action involving initial impairment of Hb catabolism, and indicate that the parasite regulates protein turnover to manage ozonide-induced damage. Author summary: The ozonides are a novel class of fully synthetic antimalarial drugs with potent activity against all parasite species that cause malaria, including the deadliest, Plasmodium falciparum. With the emergence of resistance to current frontline artemisinin-based antimalarials, new drugs are urgently needed and a clear understanding of their mechanism of action is essential so that they can be optimally deployed in the field. Here, we studied the biochemical effects of two ozonides, OZ277 (marketed in India in combination with piperaquine) and OZ439 (in Phase IIb clinical trials) in P. falciparum parasites using an untargeted multi-omics approach consisting of proteomics, peptidomics and time-dependent metabolomics, along with activity-based protease profiling. We found that the ozonides initially disrupt haemoglobin metabolism and that they likely engage the parasite proteostatic stress response. Furthermore, when the duration of ozonide exposure was extended beyond 3 hours to reflect clinically-relevant exposure periods, additional parasite biochemical pathways were perturbed. This comprehensive analysis provides new insight into the antimalarial mode of action of ozonides and provides new opportunities for interventions to enhance their antimalarial efficacy. [ABSTRACT FROM AUTHOR]

Published

2020

220. Multi-omics analysis delineates the distinct functions of sub-cellular acetyl-CoA pools in Toxoplasma gondii.

Author

Kloehn, Joachim, Oppenheim, Rebecca D., Siddiqui, Ghizal, De Bock, Pieter-Jan, Kumar Dogga, Sunil, Coute, Yohann, Hakimi, Mohamed-Ali, Creek, Darren J., and Soldati-Favre, Dominique

Subjects

ACETYLCOENZYME A, TOXOPLASMA gondii, PYRUVATE dehydrogenase complex, MITOCHONDRIAL proteins, CYTOSOL

Abstract

Background: Acetyl-CoA is a key molecule in all organisms, implicated in several metabolic pathways as well as in transcriptional regulation and post-translational modification. The human pathogen Toxoplasma gondii possesses at least four enzymes which generate acetyl-CoA in the nucleo-cytosol (acetyl-CoA synthetase (ACS); ATP citrate lyase (ACL)), mitochondrion (branched-chain α-keto acid dehydrogenase-complex (BCKDH)) and apicoplast (pyruvate dehydrogenase complex (PDH)). Given the diverse functions of acetyl-CoA, we know very little about the role of sub-cellular acetyl-CoA pools in parasite physiology. Results: To assess the importance and functions of sub-cellular acetyl-CoA-pools, we measured the acetylome, transcriptome, proteome and metabolome of parasites lacking ACL/ACS or BCKDH. We demonstrate that ACL/ACS constitute a synthetic lethal pair. Loss of both enzymes causes a halt in fatty acid elongation, hypo-acetylation of nucleo-cytosolic and secretory proteins and broad changes in gene expression. In contrast, loss of BCKDH results in an altered TCA cycle, hypo-acetylation of mitochondrial proteins and few specific changes in gene expression. We provide evidence that changes in the acetylome, transcriptome and proteome of cells lacking BCKDH enable the metabolic adaptations and thus the survival of these parasites. Conclusions: Using multi-omics and molecular tools, we obtain a global and integrative picture of the role of distinct acetyl-CoA pools in T. gondii physiology. Cytosolic acetyl-CoA is essential and is required for the synthesis of parasite-specific fatty acids. In contrast, loss of mitochondrial acetyl-CoA can be compensated for through metabolic adaptations implemented at the transcriptional, translational and post-translational level. [ABSTRACT FROM AUTHOR]

Published

2020

221. Restriction of essential amino acids dictates the systemic metabolic response to dietary protein dilution.

Author

Yap, Yann W., Rusu, Patricia M., Chan, Andrea Y., Fam, Barbara C., Jungmann, Andreas, Solon-Biet, Samantha M., Barlow, Christopher K., Creek, Darren J., Huang, Cheng, Schittenhelm, Ralf B., Morgan, Bruce, Schmoll, Dieter, Kiens, Bente, Piper, Matthew D. W., Heikenwälder, Mathias, Simpson, Stephen J., Bröer, Stefan, Andrikopoulos, Sofianos, Müller, Oliver J., and Rose, Adam J.

Subjects

LOW-protein diet, ESSENTIAL amino acids, FIBROBLAST growth factors, THREONINE, LOW-calorie diet, PROTEINS, TRYPTOPHAN, DILUTION

Abstract

Dietary protein dilution (DPD) promotes metabolic-remodelling and -health but the precise nutritional components driving this response remain elusive. Here, by mimicking amino acid (AA) supply from a casein-based diet, we demonstrate that restriction of dietary essential AA (EAA), but not non-EAA, drives the systemic metabolic response to total AA deprivation; independent from dietary carbohydrate supply. Furthermore, systemic deprivation of threonine and tryptophan, independent of total AA supply, are both adequate and necessary to confer the systemic metabolic response to both diet, and genetic AA-transport loss, driven AA restriction. Dietary threonine restriction (DTR) retards the development of obesity-associated metabolic dysfunction. Liver-derived fibroblast growth factor 21 is required for the metabolic remodelling with DTR. Strikingly, hepatocyte-selective establishment of threonine biosynthetic capacity reverses the systemic metabolic response to DTR. Taken together, our studies of mice demonstrate that the restriction of EAA are sufficient and necessary to confer the systemic metabolic effects of DPD. Dietary protein dilution, where protein is reduced and replaced by other nutrient sources without caloric restriction, promotes metabolic health via the hepatokine Fgf21. Here, the authors show that essential amino acids threonine and tryptophan are necessary and sufficient to induce these effects. [ABSTRACT FROM AUTHOR]

Published

2020

222. Comparative Metabolomics Reveals Key Pathways Associated With the Synergistic Killing of Colistin and Sulbactam Combination Against Multidrug-Resistant Acinetobacter baumannii.

Author

Han, Mei-Ling, Liu, Xiaofen, Velkov, Tony, Lin, Yu-Wei, Zhu, Yan, Creek, Darren J., Barlow, Christopher K., Yu, Heidi H., Zhou, Zhihui, Zhang, Jing, and Li, Jian

Subjects

COLISTIN, ACINETOBACTER baumannii, METABOLOMICS, PENTOSE phosphate pathway, COMBINATION drug therapy

Abstract

Background: Polymyxins are a last-line class of antibiotics against multidrug-resistant Acinetobacter baumannii. However, polymyxin resistance can emerge with monotherapy, highlighting the need for synergistic combination therapies. Polymyxins in combination with β -lactams have shown remarkable synergy against multidrug-resistant A. baumannii. Methods: Liquid chromatography–mass spectrometry-based metabolomics was conducted to investigate the metabolic perturbations in an A. baumannii clinical isolate, AB090342, in response to colistin (1 mg/L), sulbactam (128 mg/L), and their combination at 1, 4, and 24 h. Metabolomics data were analyzed using univariate and multivariate statistics, and metabolites showing ≥2-fold changes were subjected to pathway analysis. Results: The synergistic activity of colistin–sulbactam combination was initially driven by colistin through perturbation of fatty acid and phospholipid levels at 1 h. Cell wall biosynthesis was perturbed by sulbactam alone and the combination over 24 h; this was demonstrated by the decreased levels of two important precursors, uridine diphosphate- N -acetylglucosamine and uridine diphosphate- N -acetylmuramate, together with perturbed lysine and amino sugar metabolism. Moreover, sulbactam alone and the combination significantly depleted nucleotide metabolism and the associated arginine biosynthesis, glutamate metabolism, and pentose phosphate pathway. Notably, the colistin–sulbactam combination decreased amino acid and nucleotide levels more dramatically at 4 h compared with both monotherapies. Conclusions: This is the first metabolomics study revealing the time-dependent synergistic activity of colistin and sulbactam against A. baumannii , which was largely driven by sulbactam through the inhibition of cell wall biosynthesis. Our mechanistic findings may help optimizing synergistic colistin combinations in patients. [ABSTRACT FROM AUTHOR]

Published

2019

223. Contents list.

Published

2018

224. Human plasma proteome association and cytotoxicity of nano-graphene oxide grafted with stealth polyethylene glycol and poly(2-ethyl-2-oxazoline).

Author

Wang, Miaoyi, Gustafsson, Ove J. R., Siddiqui, Ghizal, Javed, Ibrahim, Kelly, Hannah G., Blin, Thomas, Yin, Hong, Kent, Stephen J., Creek, Darren J., Kempe, Kristian, Ke, Pu Chun, and Davis, Thomas P.

Published

2018

225. Benzoxaborole treatment perturbs S-adenosyl-L-methionine metabolism in Trypanosoma brucei.

Author

Steketee, Pieter C., Vincent, Isabel M., Achcar, Fiona, Giordani, Federica, Kim, Dong-Hyun, Creek, Darren J., Freund, Yvonne, Jacobs, Robert, Rattigan, Kevin, Horn, David, Field, Mark C., MacLeod, Annette, and Barrett, Michael P.

Subjects

TRYPANOSOMA brucei, TREATMENT of African trypanosomiasis, ANTIPARASITIC agents, DRUG resistance, TRYPANOSOMIASIS in animals, METHIONINE metabolism, ADENOSYLMETHIONINE, METHYLTRANSFERASES

Abstract

The parasitic protozoan Trypanosoma brucei causes Human African Trypanosomiasis and Nagana in other mammals. These diseases present a major socio-economic burden to large areas of sub-Saharan Africa. Current therapies involve complex and toxic regimens, which can lead to fatal side-effects. In addition, there is emerging evidence for drug resistance. AN5568 (SCYX-7158) is a novel benzoxaborole class compound that has been selected as a lead compound for the treatment of HAT, and has demonstrated effective clearance of both early and late stage trypanosomiasis in vivo. The compound is currently awaiting phase III clinical trials and could lead to a novel oral therapeutic for the treatment of HAT. However, the mode of action of AN5568 in T. brucei is unknown. This study aimed to investigate the mode of action of AN5568 against T. brucei, using a combination of molecular and metabolomics-based approaches.Treatment of blood-stage trypanosomes with AN5568 led to significant perturbations in parasite metabolism. In particular, elevated levels of metabolites involved in the metabolism of S-adenosyl-L-methionine, an essential methyl group donor, were found. Further comparative metabolomic analyses using an S-adenosyl-L-methionine-dependent methyltransferase inhibitor, sinefungin, showed the presence of several striking metabolic phenotypes common to both treatments. Furthermore, several metabolic changes in AN5568 treated parasites resemble those invoked in cells treated with a strong reducing agent, dithiothreitol, suggesting redox imbalances could be involved in the killing mechanism. [ABSTRACT FROM AUTHOR]

Published

2018

226. Synergistic Killing of Polymyxin B in Combination With the Antineoplastic Drug Mitotane Against Polymyxin-Susceptible and -Resistant Acinetobacter baumannii: A Metabolomic Study.

Author

Tran, Thien B., Bergen, Phillip J., Creek, Darren J., Velkov, Tony, and Li, Jian

Subjects

POLYMYXIN B, ANTINEOPLASTIC agents, ACINETOBACTER baumannii

Abstract

Polymyxins are currently used as the last-resort antibiotics against multidrug-resistant Acinetobacter baumannii. As resistance to polymyxins emerges in A. baumannii with monotherapy, combination therapy is often the only remaining treatment option. A novel approach is to employ the combination of polymyxin B with non-antibiotic drugs. In the present study, we employed metabolomics to investigate the synergistic mechanism of polymyxin B in combination with the antineoplastic drug mitotane against polymyxinsusceptible and -resistant A. baumannii. The metabolomes of four A. baumannii strains were analyzed following treatment with polymyxin B, mitotane and the combination. Polymyxin B monotherapy induced significant perturbation in glycerophospholipid (GPL) metabolism and histidine degradation pathways in polymyxin-susceptible strains, and minimal perturbation in polymyxin-resistant strains. Mitotane monotherapy induced minimal perturbation in the polymyxin-susceptible strains, but caused significant perturbation in GPL metabolism, pentose phosphate pathway and histidine degradation in the LPS-deficient polymyxin-resistant strain (FADDI-AB065). The polymyxin B - mitotane combination induced significant perturbation in all strains except the lipid A modified polymyxin-resistant FADDI-AB225 strain. For the polymyxinsusceptible strains, the combination therapy significantly perturbed GPL metabolism, pentose phosphate pathway, citric acid cycle, pyrimidine ribonucleotide biogenesis, guanine ribonucleotide biogenesis, and histidine degradation. Against FADDI-AB065, the combination significantly perturbed GPL metabolism, pentose phosphate pathway, citric acid cycle, and pyrimidine ribonucleotide biogenesis. Overall, these novel findings demonstrate that the disruption of the citric acid cycle and inhibition of nucleotide biogenesis are the key metabolic features associated with synergistic bacterial killing by the combination against polymyxin-susceptible and -resistant A. baumannii. [ABSTRACT FROM AUTHOR]

Published

2018

227. Mutations in the pantothenate kinase of Plasmodium falciparum confer diverse sensitivity profiles to antiplasmodial pantothenate analogues.

Author

Tjhin, Erick T., Spry, Christina, Sewell, Alan L., Hoegl, Annabelle, Barnard, Leanne, Sexton, Anna E., Siddiqui, Ghizal, Howieson, Vanessa M., Maier, Alexander G., Creek, Darren J., Strauss, Erick, Marquez, Rodolfo, Auclair, Karine, and Saliba, Kevin J.

Subjects

PLASMODIUM falciparum, GENETIC mutation, GENETICS, KINASES, PHOSPHOTRANSFERASES

Abstract

The malaria-causing blood stage of Plasmodium falciparum requires extracellular pantothenate for proliferation. The parasite converts pantothenate into coenzyme A (CoA) via five enzymes, the first being a pantothenate kinase (PfPanK). Multiple antiplasmodial pantothenate analogues, including pantothenol and CJ-15,801, kill the parasite by targeting CoA biosynthesis/utilisation. Their mechanism of action, however, remains unknown. Here, we show that parasites pressured with pantothenol or CJ-15,801 become resistant to these analogues. Whole-genome sequencing revealed mutations in one of two putative PanK genes (Pfpank1) in each resistant line. These mutations significantly alter PfPanK activity, with two conferring a fitness cost, consistent with Pfpank1 coding for a functional PanK that is essential for normal growth. The mutants exhibit a different sensitivity profile to recently-described, potent, antiplasmodial pantothenate analogues, with one line being hypersensitive. We provide evidence consistent with different pantothenate analogue classes having different mechanisms of action: some inhibit CoA biosynthesis while others inhibit CoA-utilising enzymes. [ABSTRACT FROM AUTHOR]

Published

2018

228. A high parasite density environment induces transcriptional changes and cell death in <italic>Plasmodium falciparum</italic> blood stages.

Author

Chou, Evelyn S., Abidi, Sabia Z., Teye, Marian, Leliwa‐Sytek, Aleksandra, Rask, Thomas S., Cobbold, Simon A., Tonkin‐Hill, Gerry Q., Subramaniam, Krishanthi S., Sexton, Anna E., Creek, Darren J., Daily, Johanna P., Duffy, Michael F., and Day, Karen P.

Subjects

CELL death, GENETIC transcription, PLASMODIUM falciparum, MALARIA, TROPHOZOITES

Abstract

Transient regulation of Plasmodium numbers below the density that induces fever has been observed in chronic malaria infections in humans. This species transcending control cannot be explained by immunity alone. Using an in vitro system we have observed density dependent regulation of malaria population size as a mechanism to possibly explain these in vivo observations. Specifically, Plasmodium falciparum blood stages from a high but not low‐density environment exhibited unique phenotypic changes during the late trophozoite (LT) and schizont stages of the intraerythrocytic cycle. These included in order of appearance: failure of schizonts to mature and merozoites to replicate, apoptotic‐like morphological changes including shrinking, loss of mitochondrial membrane potential, and blebbing with eventual release of aberrant parasites from infected erythrocytes. This unique death phenotype was triggered in a stage‐specific manner by sensing of a high‐density culture environment. Conditions of glucose starvation, nutrient depletion, and high lactate could not induce the phenotype. A high‐density culture environment induced rapid global changes in the parasite transcriptome including differential expression of genes involved in cell remodeling, clonal antigenic variation, metabolism, and cell death pathways including an apoptosis‐associated metacaspase gene. This transcriptional profile was also characterized by concomitant expression of asexual and sexual stage‐specific genes. The data show strong evidence to support our hypothesis that density sensing exists in P. falciparum. They indicate that an apoptotic‐like mechanism may play a role in P. falciparum density regulation, which, as in yeast, has features quite distinguishable from mammalian apoptosis. Database: Gene expression data are available in the GEO databases under the accession number GSE91188. [ABSTRACT FROM AUTHOR]

Published

2018

229. The Role of Metabolomics in Antiparasitic Drug Discovery.

Published

2016

230. Front Matter.

Published

2016

231. Plasma Proteome Association and Catalytic Activity of Stealth Polymer-Grafted Iron Oxide Nanoparticles.

Author

Wang, Miaoyi, Siddiqui, Ghizal, Gustafsson, Ove J. R., Käkinen, Aleksandr, Javed, Ibrahim, Voelcker, Nicolas H., Creek, Darren J., Ke, Pu Chun, and Davis, Thomas P.

Published

2017

232. Multi-omics Based Identification of Specific Biochemical Changes Associated With PfKelch13-Mutant Artemisinin-Resistant Plasmodium falciparum.

Author

Siddiqui, Ghizal, Srivastava, Anubhav, Russell, Adrian S., and Creek, Darren J.

Subjects

PLASMODIUM, ARTEMISININ, MALARIA, PLASMODIUM falciparum, PROTEOMICS, PROTEIN analysis, PROTEIN metabolism, ANTIMALARIALS, BIOCHEMISTRY, BIOLOGICAL models, DRUG resistance, GENETIC mutation, PROTEINS, PROTOZOA, PHARMACODYNAMICS

Abstract

Background: The emergence of artemisinin resistance in the malaria parasite Plasmodium falciparum poses a major threat to the control and elimination of malaria. Certain point mutations in the propeller domain of PfKelch13 are associated with resistance, but PfKelch13 mutations do not always result in clinical resistance. The underlying mechanisms associated with artemisinin resistance are poorly understood, and the impact of PfKelch13 mutations on cellular biochemistry is not defined.Methods: This study aimed to identify global biochemical differences between PfKelch13-mutant artemisinin-resistant and -sensitive strains of P. falciparum by combining liquid chromatography-mass spectrometry (LC-MS)-based proteomics, peptidomics, and metabolomics.Results: Proteomics analysis found both PfKelch13 mutations examined to be specifically associated with decreased abundance of PfKelch13 protein. Metabolomics analysis demonstrated accumulation of glutathione and its precursor, gamma-glutamylcysteine, and significant depletion of 1 other putative metabolite in resistant strains. Peptidomics analysis revealed lower abundance of several endogenous peptides derived from hemoglobin (HBα and HBβ) in the artemisinin-resistant strains.Conclusion: PfKelch13 mutations associated with artemisinin resistance lead to decreased abundance of PfKelch13 protein, decreased hemoglobin digestion, and enhanced glutathione production. [ABSTRACT FROM AUTHOR]

Published

2017

233. Global Gene Expression Profile of Acinetobacter baumannii During Bacteremia.

Author

Murray, Gerald L., Kostoulias, Xenia P., Boyce, John D., Peleg, Anton Y., Tsyganov, Kirill, Powell, David, Bulach, Dieter M., Creek, Darren J., and Paulsen, Ian T.

Subjects

GENE expression, ACINETOBACTER baumannii, BACTEREMIA, LABORATORY mice, MICROBIAL virulence, ACINETOBACTER infections, ANIMALS, ANTIBIOTICS, BACTERIAL proteins, CELL physiology, DRUG resistance in microorganisms, GENES, MICE, RNA, TOXINS, GENE expression profiling, GRAM-negative aerobic bacteria, SEQUENCE analysis, PHARMACODYNAMICS

Abstract

Background: Acinetobacter baumannii is a pathogen of major importance in intensive care units worldwide, with the potential to cause problematic outbreaks and acquire high-level resistance to antibiotics. There is an urgent need to understand the mechanisms of A. baumannii pathogenesis for the future development of novel targeted therapies. In this study we performed an in vivo transcriptomic analysis of A. baumannii isolated from a mammalian host with bacteremia.Methods: Mice were infected with A. baumannii American Type Culture Collection 17978 using an intraperitoneal injection, and blood was extracted at 8 hours to purify bacterial RNA for RNA-Seq with an Illumina platform.Results: Approximately one-quarter of A. baumannii protein coding genes were differentially expressed in vivo compared with in vitro (false discovery rate, ≤0.001; 2-fold change) with 557 showing decreased and 329 showing increased expression. Gene groups with functions relating to translation and RNA processing were overrepresented in genes with increased expression, and those relating to chaperone and protein turnover were overrepresented in the genes with decreased expression. The most strongly up-regulated genes corresponded to the 3 recognized siderophore iron uptake clusters, reflecting the iron-restrictive environment in vivo. Metabolic changes in vivo included reduced expression of genes involved in amino acid and fatty acid transport and catabolism, indicating metabolic adaptation to a different nutritional environment. Genes encoding types I and IV pili, quorum sensing components, and proteins involved in biofilm formation all showed reduced expression. Many genes that have been reported as essential for virulence showed reduced or unchanged expression in vivo.Conclusion: This study provides the first insight into A. baumannii gene expression profiles during a life-threatening mammalian infection. Analysis of differentially regulated genes highlights numerous potential targets for the design of novel therapeutics. [ABSTRACT FROM AUTHOR]

Published

2017

234. S-57-3: GUT MICROBIAL METABOLITES LOWER 24-HOUR SYSTOLIC BLOOD PRESSURE IN HYPERTENSIVE PATIENTS.

Author

Jama, Hamdi, RhysJones, Dakota, Nakai, Michael, Yao, Chu K K, Climie, Rachel E, Sata, Yusuke, Anderson, Dovile, Creek, Darren J, Head, Geoffrey A, Kaye, David M, Mackay, Charles, Muir, Jane, and Marques, Francine Z

Published

2023

235. Stage-Specific Changes in Plasmodium Metabolism Required for Differentiation and Adaptation to Different Host and Vector Environments.

Author

Srivastava, Anubhav, Philip, Nisha, Hughes, Katie R., Georgiou, Konstantina, MacRae, James I., Barrett, Michael P., Creek, Darren J., McConville, Malcolm J., and Waters, Andrew P.

Subjects

PLASMODIUM, MOSQUITOES, TRICARBOXYLIC acids, ACYCLIC acids, HOSTS (Biology)

Abstract

Malaria parasites (Plasmodium spp.) encounter markedly different (nutritional) environments during their complex life cycles in the mosquito and human hosts. Adaptation to these different host niches is associated with a dramatic rewiring of metabolism, from a highly glycolytic metabolism in the asexual blood stages to increased dependence on tricarboxylic acid (TCA) metabolism in mosquito stages. Here we have used stable isotope labelling, targeted metabolomics and reverse genetics to map stage-specific changes in Plasmodium berghei carbon metabolism and determine the functional significance of these changes on parasite survival in the blood and mosquito stages. We show that glutamine serves as the predominant input into TCA metabolism in both asexual and sexual blood stages and is important for complete male gametogenesis. Glutamine catabolism, as well as key reactions in intermediary metabolism and CoA synthesis are also essential for ookinete to oocyst transition in the mosquito. These data extend our knowledge of Plasmodium metabolism and point towards possible targets for transmission-blocking intervention strategies. Furthermore, they highlight significant metabolic differences between Plasmodium species which are not easily anticipated based on genomics or transcriptomics studies and underline the importance of integration of metabolomics data with other platforms in order to better inform drug discovery and design. [ABSTRACT FROM AUTHOR]

Published

2016

236. Population Pharmacokinetics and Pharmacodynamics of Lumefantrine in Young Ugandan Children Treated With Artemether-Lumefantrine for Uncomplicated Malaria.

Author

Tchaparian, Eskouhie, Sambol, Nancy C., Arinaitwe, Emmanuel, McCormack, Shelley A., Bigira, Victor, Wanzira, Humphrey, Muhindo, Mary, Creek, Darren J., Sukumar, Nitin, Blessborn, Daniel, Tappero, Jordan W., Kakuru, Abel, Bergqvist, Yngve, Aweeka, Francesca T., and Parikh, Sunil

Subjects

PHARMACOKINETICS, PHARMACODYNAMICS, TRIMETHOPRIM, MALARIA treatment, ANTIMALARIALS, PARASITEMIA

Abstract

Background: The pharmacokinetics and pharmacodynamics of lumefantrine, a component of the most widely used treatment for malaria, artemether-lumefantrine, has not been adequately characterized in young children.Methods: Capillary whole-blood lumefantrine concentration and treatment outcomes were determined in 105 Ugandan children, ages 6 months to 2 years, who were treated for 249 episodes of Plasmodium falciparum malaria with artemether-lumefantrine.Results: Population pharmacokinetics for lumefantrine used a 2-compartment open model with first-order absorption. Age had a significant positive correlation with bioavailability in a model that included allometric scaling. Children not receiving trimethoprim-sulfamethoxazole with capillary whole blood concentrations <200 ng/mL had a 3-fold higher hazard of 28-day recurrent parasitemia, compared with those with concentrations >200 ng/mL (P = .0007). However, for children receiving trimethoprim-sulfamethoxazole, the risk of recurrent parasitemia did not differ significantly on the basis of this threshold. Day 3 concentrations were a stronger predictor of 28-day recurrence than day 7 concentrations.Conclusions: We demonstrate that age, in addition to weight, is a determinant of lumefantrine exposure, and in the absence of trimethoprim-sulfamethoxazole, lumefantrine exposure is a determinant of recurrent parasitemia. Exposure levels in children aged 6 months to 2 years was generally lower than levels published for older children and adults. Further refinement of artemether-lumefantrine dosing to improve exposure in infants and very young children may be warranted. [ABSTRACT FROM AUTHOR]

Published

2016

237. Metabolic Dysregulation Induced in Plasmodium falciparum by Dihydroartemisinin and Other Front-Line Antimalarial Drugs.

Author

Cobbold, Simon A., Chua, Hwa H., Nijagal, Brunda, Creek, Darren J., Ralph, Stuart A., and McConville, Malcolm J.

Subjects

PLASMODIUM falciparum, ARTEMISININ, ANTIMALARIALS, DRUG resistance, DISEASE susceptibility, ACIDS, CHLOROQUINE, GAS chromatography, HEMOGLOBINS, HETEROCYCLIC compounds, MASS spectrometry, METHYLENE blue, MOLECULAR structure, PROTOZOA, ATOVAQUONE, PHARMACODYNAMICS

Abstract

Detailed information on the mode of action of antimalarial drugs can be used to improve existing drugs, identify new drug targets, and understand the basis of drug resistance. In this study we describe the use of a time-resolved, mass spectrometry (MS)-based metabolite profiling approach to map the metabolic perturbations induced by a panel of clinical antimalarial drugs and inhibitors on Plasmodium falciparum asexual blood stages. Drug-induced changes in metabolite levels in P. falciparum-infected erythrocytes were monitored over time using gas chromatography-MS and liquid chromatography-MS and changes in specific metabolic fluxes confirmed by nonstationary [(13)C]-glucose labeling. Dihydroartemisinin (DHA) was found to disrupt hemoglobin catabolism within 1 hour of exposure, resulting in a transient decrease in hemoglobin-derived peptides. Unexpectedly, it also disrupted pyrimidine biosynthesis, resulting in increased [(13)C]-glucose flux toward malate production, potentially explaining the susceptibility of P. falciparum to DHA during early blood-stage development. Unique metabolic signatures were also found for atovaquone, chloroquine, proguanil, cycloguanil and methylene blue. We also show that this approach can be used to identify the mode of action of novel antimalarials, such as the compound Torin 2, which inhibits hemoglobin catabolism. [ABSTRACT FROM AUTHOR]

Published

2016

238. LC-MS-based absolute metabolite quantification: application to metabolic flux measurement in trypanosomes.

Author

Kim, Dong-Hyun, Achcar, Fiona, Breitling, Rainer, Burgess, Karl, and Barrett, Michael

Subjects

AFRICAN trypanosomiasis, PROTOZOAN diseases, GLYCOLYSIS, METABOLITES, DRUG development

Abstract

Human African trypanosomiasis is a neglected tropical disease caused by the protozoan parasite, Trypanosoma brucei. In the mammalian bloodstream, the trypanosome's metabolism differs significantly from that of its host. For example, the parasite relies exclusively on glycolysis for energy source. Recently, computational and mathematical models of trypanosome metabolism have been generated to assist in understanding the parasite metabolism with the aim of facilitating drug development. Optimisation of these models requires quantitative information, including metabolite concentrations and/or metabolic fluxes that have been hitherto unavailable on a large scale. Here, we have implemented an LC-MS-based method that allows large scale quantification of metabolite levels by using U-C-labelled E. coli extracts as internal standards. Known amounts of labelled E. coli extract were added into the parasite samples, as well as calibration standards, and used to obtain calibration curves enabling us to convert intensities into concentrations. This method allowed us to reliably quantify the changes of 43 intracellular metabolites and 32 extracellular metabolites in the medium over time. Based on the absolute quantification, we were able to compute consumption and production fluxes. These quantitative data can now be used to optimise computational models of parasite metabolism. [ABSTRACT FROM AUTHOR]

Published

2015

239. Metabolomics continues to expand: highlights from the 2015 metabolomics conference.

Author

Fiehn, Oliver, Putri, Sastia, Saito, Kazuki, Salek, Reza, and Creek, Darren

Subjects

METABOLOMICS, INDIVIDUALIZED medicine, MASS spectrometry, SURGICAL instruments, BIOMARKERS, CONFERENCES & conventions

Abstract

Information about several topics discussed at a conference held from June 29-July 2, 2015 sponsored by Metabolomics Society in San Francisco, California on the role of metabolomics in personalized medicine is presented. Topics discussed includes omics technology in health monitoring, iknife technology combining rapid evaporative ionization mass spectrometry with electrosurgical knife and metabolic biomarkers. The conference featured several professors including Mike Snyder and Zoltan Takats.

Published

2015

240. Front Matter.

Published

2013

241. Pharmacological Metabolomics in Trypanosomes.

Published

2013

242. NormalizeMets: assessing, selecting and implementing statistical methods for normalizing metabolomics data

Author

De Livera, Alysha M., Olshansky, Gavriel, Simpson, Julie A., and Creek, Darren J.

Published

2018

243. BCKDH: The Missing Link in Apicomplexan Mitochondrial Metabolism Is Required for Full Virulence of Toxoplasma gondii and Plasmodium berghei.

Author

Oppenheim, Rebecca D., Creek, Darren J., Macrae, James I., Modrzynska, Katarzyna K., Pino, Paco, Limenitakis, Julien, Polonais, Valerie, Seeber, Frank, Barrett, Michael P., Billker, Oliver, McConville, Malcolm J., and Soldati-Favre, Dominique

Subjects

APICOMPLEXA, PLASMODIUM falciparum, TOXOPLASMA gondii, GLYCOLYSIS, GLUCOSE metabolism, VIRUS virulence, PATHOGENIC microorganisms

Abstract

While the apicomplexan parasites Plasmodium falciparum and Toxoplasma gondii are thought to primarily depend on glycolysis for ATP synthesis, recent studies have shown that they can fully catabolize glucose in a canonical TCA cycle. However, these parasites lack a mitochondrial isoform of pyruvate dehydrogenase and the identity of the enzyme that catalyses the conversion of pyruvate to acetyl-CoA remains enigmatic. Here we demonstrate that the mitochondrial branched chain ketoacid dehydrogenase (BCKDH) complex is the missing link, functionally replacing mitochondrial PDH in both T. gondii and P. berghei. Deletion of the E1a subunit of T. gondii and P. berghei BCKDH significantly impacted on intracellular growth and virulence of both parasites. Interestingly, disruption of the P. berghei E1a restricted parasite development to reticulocytes only and completely prevented maturation of oocysts during mosquito transmission. Overall this study highlights the importance of the molecular adaptation of BCKDH in this important class of pathogens. [ABSTRACT FROM AUTHOR]

Published

2014

244. Metabolite identification: are you sure? And how do your peers gauge your confidence?

Author

Creek, Darren, Dunn, Warwick, Fiehn, Oliver, Griffin, Julian, Hall, Robert, Lei, Zhentian, Mistrik, Robert, Neumann, Steffen, Schymanski, Emma, Sumner, Lloyd, Trengove, Robert, and Wolfender, Jean-Luc

Subjects

METABOLITE analysis, METABOLITE synthesis, SYSTEMS biology, METABOLOMICS, ANALYTICAL chemistry

Abstract

The authors expresses their views on the challenges in full scientific potentials for metabolomics and its essential in coverting analytical data for meaningful biological knowledge. One of the author highlights the developments in the chemical analysis working group (CAWG) of the Metabolomics Standards Initiative (MSI) for chemical analysis in metabolomics. The other author emphasizes on the importance of metabolomics reporting standards.

Published

2014

245. Benznidazole Biotransformation and Multiple Targets in Trypanosoma cruzi Revealed by Metabolomics.

Author

Trochine, Andrea, Creek, Darren J., Faral-Tello, Paula, Barrett, Michael P., and Robello, Carlos

Subjects

TRYPANOSOMA cruzi, METABOLOMICS, NEGLECTED diseases, CHAGAS' disease, BIOCONVERSION

Abstract

Background: The first line treatment for Chagas disease, a neglected tropical disease caused by the protozoan parasite Trypanosoma cruzi, involves administration of benznidazole (Bzn). Bzn is a 2-nitroimidazole pro-drug which requires nitroreduction to become active, although its mode of action is not fully understood. In the present work we used a non-targeted MS-based metabolomics approach to study the metabolic response of T. cruzi to Bzn. Methodology/Principal findings: Parasites treated with Bzn were minimally altered compared to untreated trypanosomes, although the redox active thiols trypanothione, homotrypanothione and cysteine were significantly diminished in abundance post-treatment. In addition, multiple Bzn-derived metabolites were detected after treatment. These metabolites included reduction products, fragments and covalent adducts of reduced Bzn linked to each of the major low molecular weight thiols: trypanothione, glutathione, γ-glutamylcysteine, glutathionylspermidine, cysteine and ovothiol A. Bzn products known to be generated in vitro by the unusual trypanosomal nitroreductase, TcNTRI, were found within the parasites, but low molecular weight adducts of glyoxal, a proposed toxic end-product of NTRI Bzn metabolism, were not detected. Conclusions/significance: Our data is indicative of a major role of the thiol binding capacity of Bzn reduction products in the mechanism of Bzn toxicity against T. cruzi. Author Summary: The unicellular parasite Trypanosoma cruzi infects humans, leading to Chagas disease, endemic in Central and South America and responsible for 13,000 annual deaths. Only two drugs have proven effective against Chagas, nifurtimox and benznidazole (Bzn). Bzn has the best safety and efficacy profiles and is thus used as first line treatment. Bzn is a pro-drug, and possesses a nitro group which needs to be enzymatically reduced within the parasite to become active. We have investigated for the first time, by means of mass spectrometry based metabolomics, the global changes to small metabolites that occur once Bzn enters the parasite. A decrease in the levels of several thiols, including cysteine and trypanothione, and an increase in gamma-glutamyl containing dipeptides were observed after treatment. Reduced metabolites of Bzn were also detected, together with numerous covalent conjugates of the drug combined with low molecular weight thiols and some non-thiol metabolites. Overall, Bzn treatment primarily affects thiol containing molecules in T. cruzi, and this interference with thiol metabolism contributes to the drug's mode of action. [ABSTRACT FROM AUTHOR]

Published

2014

246. Benznidazole Biotransformation and Multiple Targets in Trypanosoma cruzi Revealed by Metabolomics.

Author

Trochine, Andrea, Creek, Darren J., Faral-Tello, Paula, Barrett, Michael P., and Robello, Carlos

Subjects

NITROIMIDAZOLES, TRYPANOSOMA, TRYPANOSOMATIDAE, METABOLOMICS, TROPICAL medicine

Abstract

Background: The first line treatment for Chagas disease, a neglected tropical disease caused by the protozoan parasite Trypanosoma cruzi, involves administration of benznidazole (Bzn). Bzn is a 2-nitroimidazole pro-drug which requires nitroreduction to become active, although its mode of action is not fully understood. In the present work we used a non-targeted MS-based metabolomics approach to study the metabolic response of T. cruzi to Bzn. Methodology/Principal findings: Parasites treated with Bzn were minimally altered compared to untreated trypanosomes, although the redox active thiols trypanothione, homotrypanothione and cysteine were significantly diminished in abundance post-treatment. In addition, multiple Bzn-derived metabolites were detected after treatment. These metabolites included reduction products, fragments and covalent adducts of reduced Bzn linked to each of the major low molecular weight thiols: trypanothione, glutathione, γ-glutamylcysteine, glutathionylspermidine, cysteine and ovothiol A. Bzn products known to be generated in vitro by the unusual trypanosomal nitroreductase, TcNTRI, were found within the parasites, but low molecular weight adducts of glyoxal, a proposed toxic end-product of NTRI Bzn metabolism, were not detected. Conclusions/significance: Our data is indicative of a major role of the thiol binding capacity of Bzn reduction products in the mechanism of Bzn toxicity against T. cruzi. [ABSTRACT FROM AUTHOR]

Published

2014

247. Stable isotope-labeling studies in metabolomics: new insights into structure and dynamics of metabolic networks.

Author

Chokkathukalam, Achuthanunni, Kim, Dong-Hyun, Barrett, Michael P, Breitling, Rainer, and Creek, Darren J

Published

2014

248. Stable isotope labeled metabolomics improves identification of novel metabolites and pathways.

Author

Creek, Darren J

Published

2013

249. Mass appeal: metabolite identification in mass spectrometry-focused untargeted metabolomics.

Author

Dunn, Warwick, Erban, Alexander, Weber, Ralf, Creek, Darren, Brown, Marie, Breitling, Rainer, Hankemeier, Thomas, Goodacre, Royston, Neumann, Steffen, Kopka, Joachim, and Viant, Mark

Subjects

CAPILLARY electrophoresis, GEL electrophoresis, ZONE electrophoresis, MASS spectrometry, GAS chromatography, LIQUID chromatography

Abstract

Metabolomics has advanced significantly in the past 10 years with important developments related to hardware, software and methodologies and an increasing complexity of applications. In discovery-based investigations, applying untargeted analytical methods, thousands of metabolites can be detected with no or limited prior knowledge of the metabolite composition of samples. In these cases, metabolite identification is required following data acquisition and processing. Currently, the process of metabolite identification in untargeted metabolomic studies is a significant bottleneck in deriving biological knowledge from metabolomic studies. In this review we highlight the different traditional and emerging tools and strategies applied to identify subsets of metabolites detected in untargeted metabolomic studies applying various mass spectrometry platforms. We indicate the workflows which are routinely applied and highlight the current limitations which need to be overcome to provide efficient, accurate and robust identification of metabolites in untargeted metabolomic studies. These workflows apply to the identification of metabolites, for which the structure can be assigned based on entries in databases, and for those which are not yet stored in databases and which require a de novo structure elucidation. [ABSTRACT FROM AUTHOR]

Published

2013

250. The 2-methylcitrate cycle is implicated in the detoxification of propionate in Toxoplasma gondii.

Author

Limenitakis, Julien, Oppenheim, Rebecca D., Creek, Darren J., Foth, Bernardo J., Barrett, Michael P., and Soldati‐Favre, Dominique

Subjects

DETOXIFICATION (Alternative medicine), TOXOPLASMA gondii, COCCIDIA, INTRACELLULAR pathogens, PARASITES

Abstract

Toxoplasma gondii belongs to the coccidian subgroup of the Apicomplexa phylum. The Coccidia are obligate intracellular pathogens that establish infection in their mammalian host via the enteric route. These parasites lack a mitochondrial pyruvate dehydrogenase complex but have preserved the degradation of branched-chain amino acids ( BCAA) as a possible pathway to generate acetyl- CoA. Importantly, degradation of leucine, isoleucine and valine could lead to concomitant accumulation of propionyl- CoA, a toxic metabolite that inhibits cell growth. Like fungi and bacteria, the Coccidia possess the complete set of enzymes necessary to metabolize and detoxify propionate by oxidation to pyruvate via the 2-methylcitrate cycle (2- MCC). Phylogenetic analysis provides evidence that the 2- MCC was acquired via horizontal gene transfer. In T. gondii tachyzoites, this pathway is split between the cytosol and the mitochondrion. Although the rate-limiting enzyme 2-methylisocitrate lyase is dispensable for parasite survival, its substrates accumulate in parasites deficient in the enzyme and its absence confers increased sensitivity to propionic acid. BCAA is also dispensable in tachyzoites, leaving unresolved the source of mitochondrial acetyl- CoA. [ABSTRACT FROM AUTHOR]

Published

2013