Your search keyword '"Paul A.M. Michels"' showing total 3 results

1. Autophagy in protists

Author

Paul A.M. Michels, Patricia Silvia Romano, Rubem F. S. Menna-Barreto, Graham H. Coombs, Michael Duszenko, Michael L. Ginger, Gordon Langsley, María Isabel Colombo, Miguel Navarro, Daniel J. Rigden, Veronika Stoka, Ana Brennand, Boris Turk, Bamini Jayabalasingham, Solange L. de Castro, Isabelle Coppens, Jeremy C. Mottram, and Melisa Gualdrón-López

Subjects

Genome, Autophagy database, Drug discovery, Autophagy, Protist, Review, Cell Biology, Biology, medicine.disease_cause, Interactome, Host-Parasite Interactions, Cell biology, Evolution, Molecular, Eukaryotic Cells, medicine.anatomical_structure, Ubiquitin, Lysosome, medicine, biology.protein, Animals, Parasites, Molecular Biology, Function (biology)

Abstract

32 páginas, 11 figuras, 1 tabla.-- et al., Autophagy is the degradative process by which eukaryotic cells digest their own components using acid hydrolases within the lysosome. Originally thought to function almost exclusively in providing starving cells with nutrients taken from their own cellular constituents, autophagy is in fact involved in numerous cellular events including differentiation, turnover of macromolecules and organelles, and defense against parasitic invaders. During the last 10-20 years, molecular components of the autophagic machinery have been discovered, revealing a complex interactome of proteins and lipids, which, in a concerted way, induce membrane formation to engulf cellular material and target it for lysosomal degradation. Here, our emphasis is autophagy in protists. We discuss experimental and genomic data indicating that the canonical autophagy machinery characterized in animals and fungi appeared prior to the radiation of major eukaryotic lineages. Moreover, we describe how comparative bioinformatics revealed that this canonical machinery has been subject to moderation, outright loss or elaboration on multiple occasions in protist lineages, most probably as a consequence of diverse lifestyle adaptations. We also review experimental studies illustrating how several pathogenic protists either utilize autophagy mechanisms or manipulate host-cell autophagy in order to establish or maintain infection within a host. The essentiality of autophagy for the pathogenicity of many parasites, and the unique features of some of the autophagy-related proteins involved, suggest possible new targets for drug discovery. Further studies of the molecular details of autophagy in protists will undoubtedly enhance our understanding of the diversity and complexity of this cellular phenomenon and the opportunities it offers as a drug target., The authors gratefully acknowledge the following organizations: A.B., M.G.L. and P.A.M.M. the ‘Fonds de la Recherche Scientifique’ (FRS-FNRS) and associated foundations (FRSM and FRIA) and the Belgian Interuniversity Attraction Poles- Federal Office for Scientific, Technical and Cultural Affairs for support of their research on autophagy in trypanosomes; M.L.G. the Royal Society for an University Research Fellowship; G.L. the Wellcome Trust for a Special Initiative grant (075820/A/04/Z) for support for ‘An integrated approach for the development of sustainable methods to control tropical theileriosis’; J.C.M. and G.H.C. the Medical Research Council for support (G0700127); M.N. the MICINN for support (SAF2009-07587); B.T. and V.S. the Slovenian Research Agency for research grants (P1-0140, J1-9520, J3-2258); S.L.d.C. and R.M.B. the Brazilian agencies CNPq and Faperj; M.I.C. and P.R. the ANPCYT (PICT 2005 # 38420) and Comisión Nacional Salud Investiga in Argentina for research grants; B.T. and V.S. would like to thank Vito Turk for valuable discussions.

Published

2011

2. Autophagy and Related processes in Trypanosomatids: Insights from Genomic and Bioinformatic Analyses

Author

Paul A.M. Michels, Stuart Gillies, Daniel J. Rigden, and Murielle Herman

Subjects

Sequence Homology, Amino Acid, Autophagy database, fungi, ATG5, Autophagy, Protozoan Proteins, Computational Biology, Cell Biology, Vacuole, Biology, Genome, Cell biology, ATG12, medicine.anatomical_structure, Structural biology, Sequence Analysis, Protein, Yeasts, Lysosome, medicine, Animals, Trypanosomatina, Genome, Protozoan, Molecular Biology

Abstract

The targeting in eukaryotic cells of cellular components to the lysosome or vacuole for degradation is called autophagy. Not only cytoplasmic macromolecules and bulk cytoplasm are subject to this process; entire organelles such as peroxisomes can be degraded. Autophagy of peroxisomes is called pexophagy. Unpublished evidence suggests that the analogous processing of glycosomes in the protozoan kinetoplastids occurs. Taking advantage of the (near-) complete status of three trypanosomatid genomes, a census of components of autophagy and related processes has been undertaken in these organisms. Simple database searches were supplemented by more advanced analyses where necessary. At most, only half of the components characterized in yeasts are present in trypanosomatids suggesting an unexpectedly streamlined version of autophagy occurs in these organisms. The cytoplasm-to-vacuole targeting (Cvt) system for delivery of proteins to the vacuole seems entirely absent in trypanosomatids. The accuracy of the census is supported by the coordinated absence of functionally linked components such as the conjugation system involving ATG12, ATG5, ATG10 and ATG16 that acts at the step of vesicle expansion and completion. Overall, the results are consistent with a scenario of taxon-specific addition of components to a minimal core, a hypothesis that should be readily testable by further genomic surveys allied to laboratory experiments. A bioinformatics analysis of the trypanosomatidal proteins was carried out, highlighting the paucity of information available regarding their structures and enabling prioritization of targets for future structural biology work.

Published

2006

3. Turnover of glycosomes during life-cycle differentiation of Trypanosoma brucei

Author

Paul A.M. Michels, Murielle Herman, David Perez-Morga, and Nicolas Schtickzelle

Subjects

education.field_of_study, biology, Population, Trypanosoma brucei brucei, Protozoan Proteins, Kinetoplastida, Cell Biology, Trypanosoma brucei, Mitochondrion, biology.organism_classification, Glycosome, Microbodies, Mitochondria, medicine.anatomical_structure, Biochemistry, Lysosome, Organelle, medicine, Autophagy, Microbody, Animals, education, Lysosomes, Molecular Biology, Glycolysis

Abstract

Protozoan Kinetoplastida, a group that comprises the pathogenic Trypanosoma brucei, compartmentalize several metabolic systems such as the major part of the glycolytic pathway, in multiple peroxisome-like organelles, designated glycosomes. Trypanosomes have a complicated life cycle, involving two major, distinct stages living in the mammalian bloodstream and several stages inhabiting different body parts of the tsetse fly. Previous studies on non-differentiating trypanosomes have shown that the metabolism and enzymatic contents of glycosomes in bloodstream-form and cultured procyclic cells, representative of the stage living in the insect's midgut, differ considerably. In this study, the morphology of glycosomes and their position relative to the lysosome were followed, as were the levels of some glycosomal enzymes and markers for other subcellular compartments, during the differentiation from bloodstream-form to procyclic trypanosomes. Our studies revealed a small tendency of glycosomes to associate with the lysosome when a population of long-slender bloodstream forms differentiated into short-stumpy forms which are pre-adapted to live in the fly. The same phenomenon was observed during the short-stumpy to procyclic transformation, but then the process was fast and many more glycosomes were associated with the dramatically enlarged degradation organelle. The observations suggested an efficient glycosome turnover involving autophagy. Changes observed in the levels of marker enzymes are consistent with the notion that, during differentiation, glycosomes with enzymatic contents specific for the old life-cycle stage are degraded and new glycosomes with different contents are synthesized, causing that the metabolic repertoire of trypanosomes is, at each stage, optimally adapted to the environmental conditions encountered.

Published

2008