Your search keyword '"Sashika N. Richards"' showing total 9 results

1. The natural function of the malaria parasite’s chloroquine resistance transporter

Author

Sarah H. Shafik, Simon A. Cobbold, Kawthar Barkat, Sashika N. Richards, Nicole S. Lancaster, Manuel Llinás, Simon J. Hogg, Robert L. Summers, Malcolm J. McConville, and Rowena E. Martin

Subjects

Science

Abstract

Plasmodium falciparum chloroquine resistance transporter (PfCRT) mediates multidrug resistance, but its natural function remains unclear. Here, Shafik et al. show that PfCRT transports host-derived peptides of 4-11 residues but not other ions or metabolites, and that drug-resistance-conferring PfCRT mutants have reduced peptide transport.

Published

2020

2. Characterization of a Dopamine Transporter and Its Splice Variant Reveals Novel Features of Dopaminergic Regulation in the Honey Bee

Author

Vicky Zhang, Robert Kucharski, Courtney Landers, Sashika N. Richards, Stefan Bröer, Rowena E. Martin, and Ryszard Maleszka

Subjects

biogenic amine, dopaminergic neurons, social behavior, heteromeric protein, spliced transporter, DNA methylation, Physiology, QP1-981

Abstract

Dopamine is an important neuromodulator involved in reward-processing, movement control, motivational responses, and other aspects of behavior in most animals. In honey bees (Apis mellifera), the dopaminergic system has been implicated in an elaborate pheromonal communication network between individuals and in the differentiation of females into reproductive (queen) and sterile (worker) castes. Here we have identified and characterized a honey bee dopamine transporter (AmDAT) and a splice variant lacking exon 3 (AmDATΔex3). Both transcripts are present in the adult brain and antennae as well as at lower levels within larvae and ovaries. When expressed separately in the Xenopus oocyte system, AmDAT localizes to the oocyte surface whereas the splice variant is retained at an internal membrane. Oocytes expressing AmDAT exhibit a 12-fold increase in the uptake of [3H]dopamine relative to non-injected oocytes, whereas the AmDATΔex3-expressing oocytes show no change in [3H]dopamine transport. Electrophysiological measurements of AmDAT activity revealed it to be a high-affinity, low-capacity transporter of dopamine. The transporter also recognizes noradrenaline as a major substrate and tyramine as a minor substrate, but does not transport octopamine, L-Dopa, or serotonin. Dopamine transport via AmDAT is inhibited by cocaine in a reversible manner, but is unaffected by octopamine. Co-expression of AmDAT and AmDATΔex3 in oocytes results in a substantial reduction in AmDAT-mediated transport, which was also detected as a significant decrease in the level of AmDAT protein. This down-regulatory effect is not attributable to competition with AmDATΔex3 for ER ribosomes, nor to a general inhibition of the oocyte’s translational machinery. In vivo, the expression of both transcripts shows a high level of inter-individual variability. Gene-focused, ultra-deep amplicon sequencing detected methylation of the amdat locus at ten 5′-C-phosphate-G-3′ dinucleotides (CpGs), but only in 5–10% of all reads in whole brains or antennae. These observations, together with the localization of the amdat transcript to a few clusters of dopaminergic neurons, imply that amdat methylation is positively linked to its transcription. Our findings suggest that multiple cellular mechanisms, including gene splicing and epigenomic communication systems, may be adopted to increase the potential of a conserved gene to contribute to lineage-specific behavioral outcomes.

Published

2019

3. Molecular Mechanisms for Drug Hypersensitivity Induced by the Malaria Parasite's Chloroquine Resistance Transporter.

Author

Sashika N Richards, Megan N Nash, Eileen S Baker, Michael W Webster, Adele M Lehane, Sarah H Shafik, and Rowena E Martin

Subjects

Immunologic diseases. Allergy, RC581-607, Biology (General), QH301-705.5

Abstract

Mutations in the Plasmodium falciparum 'chloroquine resistance transporter' (PfCRT) confer resistance to chloroquine (CQ) and related antimalarials by enabling the protein to transport these drugs away from their targets within the parasite's digestive vacuole (DV). However, CQ resistance-conferring isoforms of PfCRT (PfCRTCQR) also render the parasite hypersensitive to a subset of structurally-diverse pharmacons. Moreover, mutations in PfCRTCQR that suppress the parasite's hypersensitivity to these molecules simultaneously reinstate its sensitivity to CQ and related drugs. We sought to understand these phenomena by characterizing the functions of PfCRTCQR isoforms that cause the parasite to become hypersensitive to the antimalarial quinine or the antiviral amantadine. We achieved this by measuring the abilities of these proteins to transport CQ, quinine, and amantadine when expressed in Xenopus oocytes and complemented this work with assays that detect the drug transport activity of PfCRT in its native environment within the parasite. Here we describe two mechanistic explanations for PfCRT-induced drug hypersensitivity. First, we show that quinine, which normally accumulates inside the DV and therewithin exerts its antimalarial effect, binds extremely tightly to the substrate-binding site of certain isoforms of PfCRTCQR. By doing so it likely blocks the normal physiological function of the protein, which is essential for the parasite's survival, and the drug thereby gains an additional killing effect. In the second scenario, we show that although amantadine also sequesters within the DV, the parasite's hypersensitivity to this drug arises from the PfCRTCQR-mediated transport of amantadine from the DV into the cytosol, where it can better access its antimalarial target. In both cases, the mutations that suppress hypersensitivity also abrogate the ability of PfCRTCQR to transport CQ, thus explaining why rescue from hypersensitivity restores the parasite's sensitivity to this antimalarial. These insights provide a foundation for understanding clinically-relevant observations of inverse drug susceptibilities in the malaria parasite.

Published

2016

4. Characterization of a Dopamine Transporter and Its Splice Variant Reveals Novel Features of Dopaminergic Regulation in the Honey Bee

Author

Sashika N. Richards, Courtney Landers, Stefan Bröer, Robert Kucharski, Vicky Zhang, Ryszard Maleszka, and Rowena E. Martin

Subjects

0301 basic medicine, Physiology, Dopamine transport, Biology, lcsh:Physiology, social behavior, 03 medical and health sciences, Exon, 0302 clinical medicine, biogenic amine, Dopamine, Physiology (medical), medicine, Original Research, Dopamine transporter, dopaminergic neurons, DNA methylation, lcsh:QP1-981, Alternative splicing, Dopaminergic, Transporter, Oocyte, spliced transporter, Cell biology, heteromeric protein, 030104 developmental biology, medicine.anatomical_structure, biology.protein, 030217 neurology & neurosurgery, medicine.drug

Abstract

Dopamine is an important neuromodulator involved in reward-processing, movement control, motivational responses, and other aspects of behaviour in most animals. In honey bees (Apis mellifera), the dopaminergic system has been implicated in an elaborate pheromonal communication network between individuals and in the differentiation of females into reproductive (queen) and sterile (worker) castes. Here we have identified and characterised a honey bee dopamine transporter (AmDAT) and a splice variant lacking exon 3 (AmDATdelta-ex3). Both transcripts are present in the adult brain and antennae as well as at lower levels within larvae and ovaries. When expressed separately in the Xenopus oocyte system, AmDAT localises to the oocyte surface whereas the splice variant is retained at an internal membrane. Oocytes expressing AmDAT exhibit a 12-fold increase in the uptake of [3H]dopamine relative to non-injected oocytes, whereas the AmDATdelta-ex3-expressing oocytes show no change in [3H]dopamine transport. Electrophysiological measurements of AmDAT activity revealed it to be a high-affinity, low-capacity transporter of dopamine. The transporter also recognises noradrenaline as a major substrate and tyramine as a minor substrate, but does not transport octopamine, L-Dopa, or serotonin. Dopamine transport via AmDAT is inhibited by cocaine in a reversible manner, but is unaffected by octopamine. Co-expression of AmDAT and AmDATdelta-ex3 in oocytes results in a substantial reduction in AmDAT-mediated transport, which was also detected as a significant decrease in the level of AmDAT protein. This down-regulatory effect is not attributable to competition with AmDATdelta-ex3 for ER ribosomes, nor to a general inhibition of the oocyte’s translational machinery. In vivo, the expression of both transcripts shows a high level of inter-individual variability. Gene-focused, ultra-deep amplicon sequencing detected methylation of the amdat locus at ten 5'-C-phosphate-G-3' dinucleotides (CpGs), but only in 5-10% of all reads in whole brains or antennae. These observations, together with the localization of the amdat transcript to a few clusters of dopaminergic neurons, imply that amdat methylation is positively linked to its transcription. Our findings suggest that multiple cellular mechanisms, including gene splicing and epigenomic communication systems, may be adopted to increase the potential of a conserved gene to contribute to lineage-specific behavioural outcomes.

Published

2019

5. The natural function of the malaria parasite's chloroquine resistance transporter

Author

Nicole S. Lancaster, Manuel Llinás, Sarah H. Shafik, Robert L. Summers, Simon J. Hogg, Malcolm J. McConville, Kawthar Barkat, Rowena E. Martin, Simon A. Cobbold, and Sashika N. Richards

Subjects

0301 basic medicine, Drug Resistance, Protozoan Proteins, General Physics and Astronomy, 02 engineering and technology, Vacuole, Drug resistance, Xenopus laevis, Chloroquine, Parasite physiology, Malaria, Falciparum, lcsh:Science, Multidisciplinary, biology, Membrane transport protein, 021001 nanoscience & nanotechnology, Parasite biology, Protein Transport, Female, 0210 nano-technology, Oligopeptides, geographic locations, medicine.drug, Science, Plasmodium falciparum, Biological Transport, Active, Models, Biological, General Biochemistry, Genetics and Molecular Biology, Article, Microbiology, Host-Parasite Interactions, 03 medical and health sciences, Antimalarials, parasitic diseases, medicine, Animals, Humans, Metabolomics, fungi, Membrane Transport Proteins, Transporter, General Chemistry, biology.organism_classification, Multiple drug resistance, 030104 developmental biology, Peptide transport, biology.protein, Oocytes, lcsh:Q, Mutant Proteins, Lysosomes

Abstract

The Plasmodium falciparum chloroquine resistance transporter (PfCRT) is a key contributor to multidrug resistance and is also essential for the survival of the malaria parasite, yet its natural function remains unresolved. We identify host-derived peptides of 4-11 residues, varying in both charge and composition, as the substrates of PfCRT in vitro and in situ, and show that PfCRT does not mediate the non-specific transport of other metabolites and/or ions. We find that drug-resistance-conferring mutations reduce both the peptide transport capacity and substrate range of PfCRT, explaining the impaired fitness of drug-resistant parasites. Our results indicate that PfCRT transports peptides from the lumen of the parasite’s digestive vacuole to the cytosol, thereby providing a source of amino acids for parasite metabolism and preventing osmotic stress of this organelle. The resolution of PfCRT’s native substrates will aid the development of drugs that target PfCRT and/or restore the efficacy of existing antimalarials., Plasmodium falciparum chloroquine resistance transporter (PfCRT) mediates multidrug resistance, but its natural function remains unclear. Here, Shafik et al. show that PfCRT transports host-derived peptides of 4-11 residues but not other ions or metabolites, and that drug-resistance-conferring PfCRT mutants have reduced peptide transport.

Published

2019

6. Mechanisms of resistance to the partner drugs of artemisinin in the malaria parasite

Author

Rowena E. Martin, Sashika N. Richards, and Sarah H. Shafik

Subjects

0301 basic medicine, 030106 microbiology, Drug Resistance, Drug resistance, Bioinformatics, Lumefantrine, 03 medical and health sciences, chemistry.chemical_compound, Pharmacotherapy, Piperaquine, parasitic diseases, Drug Discovery, medicine, Animals, Humans, Parasites, Artemisinin, Pharmacology, business.industry, Mefloquine, medicine.disease, Artemisinins, Malaria, Multiple drug resistance, chemistry, business, medicine.drug

Abstract

The deployment of artemisinin-based combination therapies (ACTs) has been, and continues to be, integral to reducing the number of malaria cases and deaths. However, their efficacy is being increasingly jeopardized by the emergence and spread of parasites that are resistant (or partially resistant) to the artemisinin derivatives and to their partner drugs, with the efficacy of the latter being especially crucial for treatment success. A detailed understanding of the genetic determinants of resistance to the ACT partner drugs, and the mechanisms by which they mediate resistance, is required for the surveillance of molecular markers and to optimize the efficacy and lifespan of the partner drugs through resistance management strategies. We summarize new insights into the molecular basis of parasite resistance to the ACTs, such as recently-uncovered determinants of parasite susceptibility to the artemisinin derivatives, piperaquine, lumefantrine, and mefloquine, and outline the mechanisms through which polymorphisms in these determinants may be conferring resistance.

Published

2018

7. Molecular Mechanisms for Drug Hypersensitivity Induced by the Malaria Parasite's Chloroquine Resistance Transporter

Author

Adele M. Lehane, Megan N. Nash, Michael W. Webster, Rowena E. Martin, Sarah H. Shafik, Sashika N. Richards, and Eileen S. Baker

Subjects

0301 basic medicine, Xenopus, Drug Resistance, Protozoan Proteins, Fluorescent Antibody Technique, Drug resistance, Pharmacology, Xenopus laevis, Chloroquine, Animal Cells, Medicine and Health Sciences, Parasite hosting, Protein Isoforms, Drug Interactions, Malaria, Falciparum, Biology (General), media_common, Protozoans, Quinine, biology, Membrane transport protein, Malarial Parasites, Drugs, Animal Models, 3. Good health, Chemistry, OVA, Physical Sciences, Xenopus Oocytes, Vertebrates, Frogs, Cellular Types, medicine.drug, Research Article, Drug, QH301-705.5, media_common.quotation_subject, 030106 microbiology, Blotting, Western, Plasmodium falciparum, Immunology, Research and Analysis Methods, Microbiology, Amphibians, 03 medical and health sciences, Antimalarials, Alkaloids, Model Organisms, Virology, Microbial Control, Genetics, medicine, Amantadine, Hypersensitivity, Animals, Humans, Molecular Biology, Chemical Compounds, Organisms, Membrane Transport Proteins, Biology and Life Sciences, Biological Transport, Cell Biology, RC581-607, biology.organism_classification, Parasitic Protozoans, 030104 developmental biology, Germ Cells, biology.protein, Mutagenesis, Site-Directed, Oocytes, Parasitology, Clinical Immunology, Antimicrobial Resistance, Clinical Medicine, Immunologic diseases. Allergy

Abstract

Mutations in the Plasmodium falciparum ‘chloroquine resistance transporter’ (PfCRT) confer resistance to chloroquine (CQ) and related antimalarials by enabling the protein to transport these drugs away from their targets within the parasite’s digestive vacuole (DV). However, CQ resistance-conferring isoforms of PfCRT (PfCRTCQR) also render the parasite hypersensitive to a subset of structurally-diverse pharmacons. Moreover, mutations in PfCRTCQR that suppress the parasite’s hypersensitivity to these molecules simultaneously reinstate its sensitivity to CQ and related drugs. We sought to understand these phenomena by characterizing the functions of PfCRTCQR isoforms that cause the parasite to become hypersensitive to the antimalarial quinine or the antiviral amantadine. We achieved this by measuring the abilities of these proteins to transport CQ, quinine, and amantadine when expressed in Xenopus oocytes and complemented this work with assays that detect the drug transport activity of PfCRT in its native environment within the parasite. Here we describe two mechanistic explanations for PfCRT-induced drug hypersensitivity. First, we show that quinine, which normally accumulates inside the DV and therewithin exerts its antimalarial effect, binds extremely tightly to the substrate-binding site of certain isoforms of PfCRTCQR. By doing so it likely blocks the normal physiological function of the protein, which is essential for the parasite’s survival, and the drug thereby gains an additional killing effect. In the second scenario, we show that although amantadine also sequesters within the DV, the parasite’s hypersensitivity to this drug arises from the PfCRTCQR-mediated transport of amantadine from the DV into the cytosol, where it can better access its antimalarial target. In both cases, the mutations that suppress hypersensitivity also abrogate the ability of PfCRTCQR to transport CQ, thus explaining why rescue from hypersensitivity restores the parasite’s sensitivity to this antimalarial. These insights provide a foundation for understanding clinically-relevant observations of inverse drug susceptibilities in the malaria parasite., Author Summary In acquiring resistance to one drug, many pathogens and cancer cells become hypersensitive to other drugs. This phenomenon could be exploited to combat existing drug resistance and to delay the emergence of resistance to new drugs. However, much remains to be understood about the mechanisms that underlie drug hypersensitivity in otherwise drug-resistant microbes. Here, we describe two mechanisms by which the Plasmodium falciparum ‘chloroquine resistance transporter’ (PfCRT) causes the malaria parasite to become hypersensitive to structurally-diverse drugs. First, we show that an antimalarial drug that normally exerts its killing effect within the parasite’s digestive vacuole is also able to bind extremely tightly to certain forms of PfCRT. This activity will block the natural, essential function of the protein and thereby provide the drug with an additional killing effect. The second mechanism arises when a cytosolic-acting drug that normally sequesters within the digestive vacuole is leaked back into the cytosol via PfCRT. In both cases, mutations that suppress hypersensitivity also abrogate the ability of PfCRT to transport chloroquine, thus explaining why rescue from hypersensitivity restores the parasite’s sensitivity to this antimalarial. These insights provide a foundation for understanding and exploiting the hypersensitivity of chloroquine-resistant parasites to several of the current antimalarials.

Published

2016

8. Diverse mutational pathways converge on saturable chloroquine transport via the malaria parasite's chloroquine resistance transporter

Author

Michael Lanzer, Robert L. Summers, Sashika N. Richards, Wilfred D. Stein, Kiaran Kirk, Rowena E. Martin, Megan N. Nash, Tegan J. Dolstra, Valerie Goh, Rosa V. Marchetti, Cecilia P. Sanchez, Anurag Dave, Robyn L. Schenk, and Sebastiano Bellanca

Subjects

Molecular Sequence Data, Plasmodium falciparum, Xenopus, Drug Resistance, Protozoan Proteins, Drug resistance, Biology, medicine.disease_cause, Transfection, Structure-Activity Relationship, Xenopus laevis, Chloroquine, parasitic diseases, medicine, Animals, Parasites, Amino Acid Sequence, Malaria, Falciparum, Genetics, Mutation, Multidisciplinary, Membrane transport protein, Membrane Transport Proteins, Transporter, Biological Transport, medicine.disease, biology.organism_classification, Virology, Recombinant Proteins, Kinetics, Haplotypes, PNAS Plus, biology.protein, Oocytes, Mutant Proteins, Malaria, medicine.drug

Abstract

Mutations in the chloroquine resistance transporter (PfCRT) are the primary determinant of chloroquine (CQ) resistance in the malaria parasite Plasmodium falciparum. A number of distinct PfCRT haplotypes, containing between 4 and 10 mutations, have given rise to CQ resistance in different parts of the world. Here we present a detailed molecular analysis of the number of mutations (and the order of addition) required to confer CQ transport activity upon the PfCRT as well as a kinetic characterization of diverse forms of PfCRT. We measured the ability of more than 100 variants of PfCRT to transport CQ when expressed at the surface of Xenopus laevis oocytes. Multiple mutational pathways led to saturable CQ transport via PfCRT, but these could be separated into two main lineages. Moreover, the attainment of full activity followed a rigid process in which mutations had to be added in a specific order to avoid reductions in CQ transport activity. A minimum of two mutations sufficed for (low) CQ transport activity, and as few as four conferred full activity. The finding that diverse PfCRT variants are all limited in their capacity to transport CQ suggests that resistance could be overcome by reoptimizing the CQ dosage.

Published

2014

9. Roquin binds microRNA-146a and Argonaute2 to regulate microRNA homeostasis

Author

Toyoyuki Ose, E. Yvonne Jones, Nicholas E. Dixon, Carola G. Vinuesa, Anil Verma, Thomas Preiss, Monika Srivastava, Janet H. C. Yeo, Desheng Hu, Vicki Athanasopoulos, Vigo Heissmeyer, Hardip R. Patel, Guowen Duan, Slobodan Jergic, Sashika N. Richards, Nadia J. Kershaw, Simon H. J. Brown, Alvin Pratama, Jeffrey J. Babon, and Mark M.W. Chong

Subjects

Ribonuclease III, RNA Stability, T-Lymphocytes, Ubiquitin-Protein Ligases, General Physics and Astronomy, RNA-binding protein, Biology, Crystallography, X-Ray, General Biochemistry, Genetics and Molecular Biology, Article, Transcription (biology), microRNA, Gene silencing, Animals, Homeostasis, Humans, RNA Processing, Post-Transcriptional, Multidisciplinary, HEK 293 cells, RNA, General Chemistry, Argonaute, Molecular biology, 3. Good health, Protein Structure, Tertiary, Mice, Inbred C57BL, MicroRNAs, HEK293 Cells, Argonaute Proteins, biology.protein, Half-Life, Protein Binding

Abstract

Roquin is an RNA-binding protein that prevents autoimmunity and inflammation via repression of bound target mRNAs such as inducible costimulator (Icos). When Roquin is absent or mutated (Roquinsan), Icos is overexpressed in T cells. Here we show that Roquin enhances Dicer-mediated processing of pre-miR-146a. Roquin also directly binds Argonaute2, a central component of the RNA-induced silencing complex, and miR-146a, a microRNA that targets Icos mRNA. In the absence of functional Roquin, miR-146a accumulates in T cells. Its accumulation is not due to increased transcription or processing, rather due to enhanced stability of mature miR-146a. This is associated with decreased 3′ end uridylation of the miRNA. Crystallographic studies reveal that Roquin contains a unique HEPN domain and identify the structural basis of the ‘san’ mutation and Roquin’s ability to bind multiple RNAs. Roquin emerges as a protein that can bind Ago2, miRNAs and target mRNAs, to control homeostasis of both RNA species., Roquin is an RNA-binding protein that promotes the degradation of specific mRNAs and is crucial for the maintenance of peripheral immune tolerance. Here the authors show that, in addition to its target mRNAs, Roquin can bind miR-146a and the RISC component Ago2 to control homeostasis of both RNA species.

Published

2015