Etude fonctionnelle de la β-oxydation chez la levure pathogène opportuniste Candida lusitaniae : caractérisation d’une voie mitochondriale et peroxysomale Fox2p-dépendante et mise en évidence d’une voie peroxysomale alternative Fox2p-indépendante de catabolisme des acides gras / Functional study of fatty acid β-oxidation in the opportunistic pathogen yeast Candida lusitaniae : characterization of a mitochondrial and a peroxisomal Fox2p-dependant pathway and evidences for an alternative peroxisomal Fox2p-independent pathway for fatty acid catabolism

Gabriel, Frédéric

15 December 2011

Les levures Candida sont des pathogènes opportunistes émergents. Après phagocytose macrophagique, C. albicans reprogramme son métabolisme pour faire face à une carence carbonée et induit 2 voies métaboliques, le cycle du glyoxylate et la β-oxydation. Notre objectif est d’étudier le lien entre β-oxydation, capacité de résistance à la phagocytose et virulence dans notre modèle biologique C. lusitaniae. Chez les levures Ascomycètes la β-oxydation, essentielle pour dégrader les acides gras (AG), est présumée être exclusivement peroxysomale.Nous avons construit 3 mutants nuls chez C. lusitaniae : icl1Δ, fox2Δ et pxa1Δ, respectivement défectifs pour l’isocitrate lyase (enzyme clé du cycle du glyoxylate), pour la protéine multifonctionnelle de la β-oxydation et pour une protéine responsable de l’import peroxysomal des AG à longue chaîne. L’étude de l’assimilation des AG et du catabolisme du 14Calpha-palmitoyl-CoA a révélé que les acyl-CoA à longue chaîne étaient toujours dégradés chez fox2Δ. L’étude du catabolisme des AG dans les fractions peroxysomale et mitochondriale des souches sauvage et fox2Δ, l’immunolocalisation de la protéine Fox2p et la mesure de la respiration mitochondriale nous ont permis de montrer pour la première fois chez une levure Ascomycète l’existence d’une β-oxydation Fox2p-dépendante dans la mitochondrie. C’est aussi la première démonstration chez un organisme eucaryote de la double localisation peroxysomale et mitochondriale de Fox2p. L’invalidation des gènes FOX1 et FOX3 (acyl-CoA oxydase et kétoacyl-CoA thiolase) a confirmé pour la première fois chez les champignons l’existence d’une voie peroxysomale alternative de catabolisme des AG, Fox2p-indépendante / The Candida spp. are emerging opportunistic pathogens. Phagocytic cells are a primary line of defense against these opportunistic pathogens. Upon phagocytosis by macrophages, C. albicans reprograms its metabolism because genes involved in the peroxisomal metabolism, such as glyoxylic acid cycle and beta-oxidation pathway, are overexpressed. The objective of this study was to study the relation between fatty acid beta-oxidation, resistance to phagocytosis and virulence in the biological model Candida lusitaniae. In ascomycetous yeasts, the fatty acid β-oxidation is assumed to be exclusively located to peroxisomes.We constructed three null-mutants in C. lusitaniae: icl1Δ, fox2Δ et pxa1Δ, respectively lacking the isocitrate lyase (a key enzyme of the glyoxylate cycle), the multifunctional fatty acid beta-oxidation protein (essential in C. albicans to the β-oxidation pathway), and a protein involved in the peroxisomal import of long-chain fatty acids. The study of fatty acid assimilation and 14Calpha-palmitoyl-CoA catabolism revealed that long-chain fatty acids were still catabolized in fox2Δ. The observation of 14Calpha-palmitoyl-CoA catabolism in mitochondrial and peroxisomal fractions of wild-type and fox2Δ strains, the immunolocalization of Fox2p and mitochondrial respiration measurements yielded to the first demonstration in ascomycetous yeast of a mitochondrial Fox2p-dependent fatty acid β-oxidation pathway. We also demonstrated for the first time in Eucaryota that Fox2p co-localized in both peroxisomes and mitochondria. The invalidation of FOX1 and FOX3 genes (acyl-CoA oxidase and ketoacyl-CoA thiolase, respectively) confirmed for the first time in Fungi the existence of an alternative peroxisomal pathway for fatty acid catabolism, Fox2p-independently.

Candida

Cycle du glyoxylate

ß-oxydation

Acides gras

FOX1

FOX2

FOX3

PXA1

ICL1

Mitochondries

Peroxysomes

Candida

Glyoxylate cycle

Β-oxidation

Fatty acids

FOX1

FOX2

FOX3

PXA1

ICL1

Mitochondria

Peroxisomes

Aufreinigung und funktionelle Charakterisierung der peroxisomalen ABC-Transporter Pxa1p-Pxa2p aus Saccharomyces cerevisiae

Schreiber, Gabriele

19 December 2007

Die peroxisomalen ABC-Transporter Pxa1p und Pxa2p sind Halbtransporter. Genetische Studien ergaben Hinweise, dass sie zur Bildung aktiver Transporter heterodimerisieren und am Import von langkettigen Fettsäuren in die Peroxisomen von S. cerevisiae beteiligt sind. Es wurden epitopmarkierte Varianten der Proteine als Komplex isoliert. Damit wurde gezeigt, dass Pxa1p und Pxa2p ein stabiles Heterodimer bilden. Zur Charakterisierung der ATP Bindeeigenschaften wurden die Transporter mit 8-azido-[alpha-32P]-ATP inkubiert und kovalent verknüpft. Dabei konnte gezeigt werden, dass Pxa1p und Pxa2p eine unsymmetrische Bindung des ATP Analogons aufweisen. Pxa2p bindet deutlich mehr azido-ATP als Pxa1p, bei sehr ähnlichen Dissoziationskonstanten. Die reduzierte ATP Bindung von Pxa1p spiegelt sich durch degenerierte Sequenzmotive der an der ATP Bindung beteiligten Sequenzen wieder. Die isolierten ABC-Transporter wurden für ATPase Messungen eingesetzt. Sie zeigten eine basale ATPase Aktivität, die durch Zugabe langkettiger Coenzym A aktivierter Fettsäuren, wie Oleoyl-CoA und Palmitoyl-CoA stimulierbar war. Eine Lysin Mutation im Walker A Motiv von Pxa1p hatte keine Funktionalitätseinbuße zur Folge. Dieselbe Mutation bei Pxa2p führte im Wachstumstest auf Festmedium mit Ölsäure als Kohlenstoffquelle zu einem deutlich verlangsamten Wachstum. Diese Ergebnisse korrespondieren mit der beobachteten unsymmetrischen ATP Bindung von Pxa1p und Pxa2p, da bei dem schwächer bindenden Pxa1p die Mutation wirkungslos blieb. Keine Übereinstimmung war bei den ATPase Aktivitätsmessungen der aufgereinigten Mutanten zu verzeichnen. Beide Mutanten zeigten eine unbeeinträchtigte ATPase Aktivität. Die ABC-Transporter wurden in Proteoliposomen eingebaut und für Transportmessungen mit einem Spin-Label markierten Oleoyl-CoA verwendet. Die Transportmessungen zeigten einen ATP abhängigen Transport, woraus geschlossen wurde, dass Pxa1p-Pxa2p tatsächlich Coenzym A Ester langkettiger Fettsäuren transportiert. / The peroxisomal ABC-transporters Pxa1p and Pxa2p are half transporters. Previous genetic investigations have demonstrated that Pxa1p and Pxa2p have to dimerise in order to build a functional transporter, which is very likely involved in the import of long chain fatty acids into peroxisomes of S. cerevisiae. In this work, tagged versions of the proteins were purified as a complex. This proved for the building of a stable hetero dimer. For characterisation of the ATP binding properties, the transporters were incubated and cross linked with 8-azido-[alpha-32P]-ATP. This revealed an asymmetric binding of the ATP analogue. Pxa2p binds much more azido-ATP, than Pxa1p, while the dissociation constants are rather similar. The poorer ATP binding of Pxa1p is reflected by degenerated sequence motifs in the nucleotide binding fold. The purified ABC-transporters have been used for ATPase assays. They showed a basal ATPase activity, which could be stimulated by addition of long chain fatty acid CoAs, like oleoyl-CoA and palmitoyl-CoA. Mutants with a lysine mutation in the walker A motive of Pxa1p led to no functional impairment, while the corresponding lysine mutation in Pxa2p led to reduced growth on agar plates with oleic acid as sole carbon source. The result corresponds with the ATP binding properties of Pxa1p. Because of the poorer ATP binding, even in the wild type protein, the mutation was not supposed to have a big influence. No accordance was found in respect to the ATPase measurements of the isolated mutant proteins. Both mutants revealed unaffected ATPase activity. The purified ABC-transporters were reconstituted in proteoliposomes and used for translocation assays of a spin-labelled oleoyl-CoA derivative. The measurements revealed an ATP dependent transport of the oleoyl-CoA analogue. This led to the conclusion, that Pxa1p-Pxa2p is indeed the transporter of long chain acetyl CoA esters, which were transported in an ATP dependent manner.

ABC-Transporter

Peroxisomen

Fettsäuretransport

ATPase Aktivität

SL-Oleoyl-CoA

Flippase

Rekonstitution

ABC-transporter

peroxisomes

fatty acid transport

ATPase activity

SL-Oleoyl-CoA

flippase

reconstitution

570 Biowissenschaften, Biologie

32 Biologie

WD 5100

WF 9500

ddc:570

Development and application of a proteomic approach to the assessment of pollution in the marine environment

Apraiz Larrucea, Itxaso

January 2009

Today, assessment of the health of coastal waters is recognized as being important for both the conservation of nature and well-being of humans. Anthropogenic pollution has been the focus of extensive research for some time and a variety of programs for the monitoring and assessment of environmental pollution have been developed. Determination of the levels of pollution in sensitive ‘sentinels’ such as mussels, allows monitoring of these levels in a given area over a prolonged period of time. Furthermore, the biological effects of pollution are reflected in a series of biomarkers, none of which provides a general picture of the sentinel’s state of health and all of which are individually specific for certain pollutants and influenced by both biotic and abiotic factors. In an attempt to improve biomonitoring of marine pollution, we have developed two proteomic approaches here. In the first portion of the thesis, a proteomic analysis was performed on peroxisomes isolated from mussels exposed either to one of three model anthropogenic pollutants, or two different types of crude oil, or from mussels exposed to the Prestige oil spill. Application of two-dimensional electrophoresis (2-DE) provided protein expression signatures (PES) for exposure to these different pollutants.Furthermore, several individual protein components of these PES could be putatively identified. In the second portion of this work, such analysis of subproteomes was developed further in order to improve the applicability of this approach to biomonitoring. A simple fractionation procedure in combination with liquid chromatography and 2-DE provided samples from mussels residing in different regions of a pollution gradient around the harbor of Gothenburg, as well as from mussels exposed to two types of fuel oil similar to that of the Prestige that were suitable for environmental proteomics. In addition, we constructed a model for this approach that can be cross-validated in the future and applied to assess sources of fuel oil pollution in connection with biomonitoring programs.

proteomics

mussels

peroxisomes

two-dimensional electrophoresis (2-DE)

difference gel electrophoresis (DIGE)

bisphenol A (BPA)

diallyl phthalate (DAP)

2

2′

4

4′-tetrabromodiphenyl ether (PBDE-47)

fuel oil

Prestige oil spill

Environmental toxicology

Miljötoxikologi

Toxicology

Toxikologi

Investigations of lipid metabolism in Yarrowia lipolytica

Blocher-Smith, Ethan Charles

31 July 2014

Indiana University-Purdue University Indianapolis (IUPUI) / An investigation of the lipid metabolism pathway in the yeast Yarrowia lipolytica was conducted. Yarrowia is an oleaginous ascomycete that is capable of growing on many different substrates, which derives its name from its high efficiency of growth on lipids. Once the exogenous lipids are converted into free fatty acids and internalized by the yeast, the primary mode of degradation is through β-oxidation mediated by the peroxisomal oxidases, or POX genes. These enzymes catalyze the formation of a trans double bond, producing the trans-2-enoyl product. Our study looked at the comparison of the Y. lipolytica prototrophic strain against a knockout of the Pox2 gene on the uptake, incorporation, and degradation of relevant fatty acids. To construct this gene knockout, a novel gene deletion method using a combination of Cre recombinase and the AHAS* gene was synthesized, developed, and tested successfully. This knockout system allows for serial deletion of genes with the use of only one resistance marker, with excision of the marker after selection.

Yarrowia lipolytica

Pox2

Peroxisomal Oxidase

pCre-AHAS*

Cre Recombinase

Single Resistance Knockouts

Biochemistry -- Research -- Evaluation

Lipids -- Metabolism

Lipid membranes -- Metabolism

Fatty acids -- Metabolism -- Regulation

Dipodascaceae

Yeast -- Physiology

Yeast fungi

Ascomycetes

Peroxisomes

Oxidases

Gene targeting

The role of alpha oxidation in lipid metabolism

Jenkins, Benjamin John

January 2018

Recent findings have shown an inverse association between the circulating levels of pentadecanoic acid (C15:0) and heptadecanoic acid (C17:0) with the risk of pathological development in type 2 diabetes, cardio vascular disease and neurological disorders. From previously published research, it has been said that both these odd chain fatty acids are biomarkers of their dietary intake and are significantly correlated to dietary ruminant fat intake. However, there are profound studies that show the contrary where they do not display this biomarker correlation. Additionally, several astute studies have suggested or shown odd chain fatty acid endogenous biosynthesis, most often suggested via alpha oxidation; the cleavage of a single carbon unit from a fatty acid chain within the peroxisomes. To better understand the correlations and interactions between these two fatty acids with pathological development, the origin of these odd chain fatty acids needed to be determined, along with confirming their association with the disease aetiology. To minimise animal & human experimentation we made use of existing sample sets made available through institutional collaborations, which produced both animal and human interventional study samples suitable for odd chain fatty acid investigations. These sample collaborations allowed us to comprehensively investigate all plausible contributory sources of these odd chain fatty acids; including from the intestinal microbiota, from dietary contributions, and derived from novel endogenous biosynthesis. The investigations included two intestinal germ-free studies, two ruminant fat diet studies, two dietary fat studies and an ethanol intake study. Endogenous biosynthesis was assessed through: a stearic acid infusion, phytol supplementation, and an Hacl1 knockout mouse model. A human dietary intervention study was used to translate the results. Finally, a study comparing circulating baseline C15:0 and C17:0 levels with the development of glucose intolerance. We found that the circulating C15:0 and C17:0 levels were not significantly influenced by the presence or absence of intestinal microbiota. The circulating C15:0 levels were significantly and linearly increased when the C15:0 dietary composition increased; however, there was no significant correlation in the circulating C17:0 levels with intake. Circulating levels of C15:0 were affected by the dietary composition and factors affecting the dietary intake, e.g. total fat intake and ethanol, whereas circulating C17:0 levels were found to be independent of these variables. In our studies, the circulating C15:0 levels were not significantly affected by any expected variations in alpha oxidation caused by pathway substrate inhibition or gene knockout. However, C17:0 was significantly related, demonstrating it is substantially endogenously biosynthesised. Furthermore, we found that the circulating C15:0 levels, when independent of any dietary variations, did not correlate with the progression of glucose intolerance when induced, but the circulating C17:0 levels did significantly relate and linearly correlated with the development of glucose intolerance. To summarise, the circulating C15:0 and C17:0 levels were independently derived; the C15:0 levels substantially correlated with its dietary intake, whilst the C17:0 levels proved to be separately derived from its endogenous biosynthesis via alpha oxidation of stearic acid. C15:0 was found to be minimally endogenously biosynthesised via a single cycle of beta oxidation of C17:0 in the peroxisomes, however, this did not significantly contribute to the circulating levels of C15:0. Additionally, only the baseline levels of C17:0 significantly correlated with the development of glucose intolerance. These findings highlight the considerable differences between both of these odd chain fatty acids that were once thought to be homogeneous and similarly derived. On the contrary, they display profound dietary, metabolic, and pathological differences.