Characterization of a glycerophosphodiester phosphodiesterase in the human malaria parasite Plasmodium falciparum

Denloye, Titilola Ifeoma

08 June 2012

Active lipid metabolism is a key process required for the intra-erythrocytic development of the malaria parasite, Plasmodium falciparum. Enzymes that hydrolyze host-derived lipids play key roles in parasite growth, virulence, differentiation, cell-signaling and hemozoin formation. Therefore, investigating enzymes involved in lipid degradation could uncover novel drug targets. We have identified in P. falciparum, a glycerophosphodiester phosphodiesterase (PfGDPD), involved in the downstream pathway of phosphatidylcholine degradation. PfGDPD hydrolyzes deacylated phospholipids, glycerophosphodiesters to glycerol-3-phosphate and choline. In this study, we have characterized PfGDPD using bioinformatics, biochemical and genetic approaches. Knockout experiments showed a requirement for PfGDPD for parasite survival. Sequence analysis revealed PfGDPD possesses the unique GDPD insertion domain sharing a cluster of conserved residues present in other GDPD homologues. We generated yellow fluorescent fusion proteins that revealed a complex distribution of PfGDPD within the parasite cytosol, parasitophorous vacuole and food vacuole. To gain insight into the role of PfGDPD, sub-cellular localization was modulated and resulted in a shift in protein distribution, which elicited no growth phenotype. Kinetic analyses suggest PfGDPD activity is Mg₂⁺ dependent and catalytically efficient at the neutral pH environment of the parasitophorous vacuole. Next, our aim was to determine the upstream pathway that provides deacylated glycerophosphodiesters as substrate for PfGDPD. We identified via bioinformatics, a P. falciparum lysophospholipase (PfLPL1) that directly generates the substrate. Knockout clones were generated and genotyped by Southern and PCR analysis. The effects of PfLPL1 knockouts on parasite fitness were studied, and the results showed that PfLPL1was not required for parasite survival and proliferation. / Ph. D.

choline

lipid metabolism

fatty acid

malaria

glycerophosphodiester phosphodiesterase

Plasmodium falciparum

Identification and functional characterization of acyl-CoA:lysocardiolipin acyltransferase 2 (ALCAT2)

Bradley, Ryan

21 May 2015

The human genome project has allowed for the rapid identification of a large number of protein families based on similarities in their genetic sequences. The acyl-glycerol phosphate acyltransferase (AGPAT) family of enzymes have been largely identified through sequence homology, with eleven isoforms identified in both mice and humans. Interestingly, very little work has been done on the characterization of AGPAT isoform 4. In the present study, I report the functional characterization of AGPAT4 as an acyl-CoA: lysocardiolipin acyltransferase (ALCAT), which we have renamed ALCAT2. Although ALCAT2 is present in most tissues, it is abundant in multiple brain regions including olfactory bulbs, hippocampus, cerebellum, cortex, and brain stem, and is detectable in both primary neurons and glial cells. In assays performed in vitro, ALCAT2 significantly increased the incorporation of [14C]oleoyl-CoA into phosphatidylinositol and CL using either lysophosphatidylinositol, or monolysocardiolipin or dilysocardiolipin as acyl acceptors, respectively. ALCAT2 did not display significant acyltransferase activity with lysophosphatidic acid, lysophosphatidylcholine, lysophosphatidylethanolamine, lysophosphatidylserine, or lysophosphatidylglycerol acyl acceptors. Overexpressing ALCAT2 in HEK-293 cells increased the total CL content, but did not significantly affect levels of other glycerophospholipids including phosphatidylinositol. Analysis of the fatty acyl profile of CL from ALCAT2-overexpressing cells indicated increased total saturated fatty acids, particularly stearate, palmitate, and myristate, and increased levels of n-3 polyunsaturated fatty acids α-linolenic acid (18:3n-3), eicosatrienoic acid (20:3n-3), and eicosapentanoic acid (20:5n-3). In accordance with its observed role in cardiolipin remodeling, ALCAT2 localized predominately to the mitochondria. ALCAT2 was also regulated during embryogenesis, and in varying metabolic states. In summary, ALCAT2 is a new enzyme in CL remodeling with a potential role in mitochondrial function.

Mitochondria

Brain

Brain lipid metabolism

Lipid metabolism

Cardiolipin

Phospholipid synthesis and remodeling

Kennedy Pathway

Lands Pathway

Low density lipoprotein receptor-related protein (LRP) and its mRNA : influence of genetic polymorphisms, a fat load and statin therapy

Pocathikorn, Anothai

January 2006

[Truncated abstract] The low density lipoprotein receptor-related protein (LRP), a member of the low-density lipoprotein (LDL) receptor gene family is involved in numerous biological processes including lipoprotein metabolism. This thesis concerns investigations into some aspects of LRP metabolism/regulation and possible roles in coronary artery disease (CAD). Specific aims were: to investigate the association between polymorphisms in the LRP gene and in its associated protein, the lipoprotein receptor-associated protein (RAP), with the risk of CAD; to extensively examine the influence of the LRP exon 22 C200T polymorphism on lipid metabolism; to develop and characterise assays for the mRNA expression of LRP and 2 other genes relevant to lipid metabolism, the LDL receptor (LDLR), and HMG CoA reductase (HMGCR); and finally, to apply the latter techniques to studies on the influence of genetic variation in LRP, and dietary and drug interventions, on LRP, LDLR and HMGCR mRNA expression in nucleated blood cells from healthy human subjects. Six hundred CAD subjects and 700 similarly aged controls were genotyped for 8 LRP gene polymorphisms as well as for the RAP V311M polymorphism. ... In the final phase of my studies, I examined the influence of 4 weeks therapy with a cholesterol lowering drug, an HMGCR inhibitor, atorvastatin (20mg daily), on the mRNA expression of LDLR, LRP and HMGCR in human nucleated blood cells. Twelve normal Caucasian male subjects aged 49 ? 5 (SD) years were studied. Plasma total cholesterol and LDL-C decreased by averages of 29 % and 41 % after the 4 week period. This was accompanied by an elevation in LDLR mRNA expression by approximately 30 35 %. In contrast, there was no significant effect on LRP and HMGCR mRNA expression. In conclusion, the original findings in this thesis included: demonstration of a strong influence of the LRP exon 22 C200T polymorphism on coronary artery disease and LDLR expression, but without a clear effect on fasting or postprandial lipid levels; data on the biological variation in LDLR and LRP gene expression in nucleated blood cells from normal subjects; the influence of an oral fat load on the expression viii of these genes, finding that LDLR was significantly depressed; and finally, the observation that statin therapy upregulated LDLR in nucleated blood cells.

Lipoproteins -- Receptors

Atherosclerosis -- Genetic aspects

Messenger RNA

Lipid metabolism

Coronary heart disease

Lipoprotein metabolism

Postprandial lipid metabolism

Genetic polymorphisms

MRNA quantification

Hepatocellular lipid metabolism in Hepatitis C Virus infection

Beer, Melanie

January 2014

The work described in this thesis investigates the lipid metabolism of human hepatocytes in the context of Hepatitis C Virus (HCV) infection. This includes lipoprotein signalling and cholesterol metabolism targeted analysis of gene expression as well as the influence of polyunsaturated ER targeting liposomes (PERLs) on infection. These analyses indicate that HCV suppresses the expression of key regulators throughout the cholesterol biosynthesis pathway. This effect was quantified and the influence of liposome treatment evaluated. The latter resulted in the formulation of the hypothesis that PERL treatment interfers with virus-induced abberations of the cholesterol biosynthesis pathway and normalises the expression of four genes directly involved in cholesterol regulation. In addition, the lipidome of isolated lipid droplet was analysed by mass spectrometry. These data, combined with microscopy data suggest that PERLs interfere with S-palmitoylation of the HCV core protein resulting in dissociation of core from lipid droplets. This is likely to interrupt the viral assembly process, leading to inhibition of the production of infectious viral particles. Further described here are two different yet unsuccessful approaches to fluorescently label HCV RNA for live cell microscopy studies, namely an MS2 coat protein mediated approach, and Alexa®UTP labelling.

616.3

ZHX2 REGULATION OF LIPID METABOLISM AND THE BALANCE BETWEEN CARDIOVASCULAR AND HEPATIC HEALTH

Creasy, Kate Townsend

01 January 2015

The growing obesity epidemic in America carries with it numerous health risks, including diabetes, increased serum lipid levels, and excess fat accumulation in the liver. If these conditions persist or become exacerbated, they may lead to the development of cardiovascular disease, the current leading cause of death among Americans, or to nonalcoholic fatty liver disease (NAFLD) which can progress to hepatocellular carcinoma (HCC), one of the deadliest forms of cancer. Better understanding of the genes involved in these diseases can lead to improved identification of at-risk individuals and treatment strategies. Our lab previously identified zinc fingers and homeoboxes 2 (Zhx2) as a regulator of hepatic gene expression. The BALB/cJ mouse strain has a hypomorphic mutation in the Zhx2 gene, causing a 95% reduction in Zhx2 protein expression. The near ablation of Zhx2 in BALB/cJ mice confers protection from cardiovascular disease when fed a high fat diet, yet these mice show increased hepatic lipid accumulation and liver damage. Microarray data indicates Zhx2 may be involved in the regulation of numerous genes involved in lipid metabolism. Recent GWAS studies indicate ZHX2 may contribute to the risk of cardiovascular disease and liver damage in humans as well. In this dissertation, I characterize the role of Zhx2 expression in the liver and how it affects the risk of both cardiovascular disease and liver damage. I generated liver-specific Zhx2 knockout mice and confirmed Zhx2 regulates several novel targets that could contribute to the fatty liver phenotype seen in BALB/cJ mice. Further studies revealed that hepatic Zhx2 expression is necessary for proper sex-specific expression of several Cyptochrome P450 (CYP) genes and could contribute to gender differences in disease susceptibility. Lastly, I performed studies into the functional role of the Zhx2 target gene Elovl3. A mouse model of HCC revealed that Elovl3 is completely repressed in HCC tumors. Cell viability and cell cycle assays indicate that Elovl3 expression slows cell proliferation and may be important for proper cell cycle checkpoints. Together, these data indicate that Zhx2 and/or its targets could be clinically relevant in the detection, prevention, or treatment of cardiovascular disease, fatty liver, and HCC.

Zinc fingers and homeoboxes 2

gene regulation

lipid metabolism

cancer

cardiovascular disease

ROLE OF LIPIDS IN TOMBUSVIRUS REPLICATION

Sharma, Monika

01 January 2011

Positive-strand RNA virus group are the most abundant among viruses affecting plants and animals. To successfully achieve replication, these viruses usurp or co-opt host proteins. To facilitate the discovery of host factors involved in Tomato bushy stunt virus (TBSV), yeast has been developed as a surrogate model host. Genome-wide approaches covering 95% of yeast genes, has revealed approximately hundred factors that could affect virus replication. Among the identified host factors, there are fourteen yeast genes, which affect/regulate lipid metabolism of the host. One of the identified host gene is ERG25, which is an important factor for sterol biosynthesis pathway, affecting viral replication. Sterols present in eukaryotes affect the lipid composition of membranes, where tombusviruses, similar to other plus-strand viruses of tobacco, replicate. Since potent inhibitors of sterol synthesis are known, I have tested their effects on tombusvirus replication. We demonstrated that these sterolsynthesis inhibitors reduced virus replication in tobacco protoplasts. Virus replication is resumed to the wild type level by providing phytosterols in tobacco protoplasts confirming the role of sterols in RNA virus replication in tobacco. We have also identified INO2, a transcription factor for many phospholipid biosynthetic genes, reduces virus replication in its deletion background. When we provided this gene product in the mutant background, viral replication was back to normal, confirming the role of Ino2p in tombusvirus replication. Further biochemical assays showed that the viral inhibition is because of alteration in the formation of the viral replicase complex. Using confocal microscopy, we showed that the viral replication protein, termed p33, is forming large and few punctate structures rather than the small and many by overexpressing Ino2p in the wild type yeast cells. Over-expression of Opi1, an inhibitor of Ino2p led to greatly reduced viral replication, further supporting the roles of the phospholipid pathway in tombusvirus replication. One of the phospholipid, which is regulated by this pathway, is cardiolipin an important component of the mitochondrial as well as peroxisomal membranes. We further characterized how cardiolipin is playing an important role for tombusvirus replication by using different biochemical approaches.

Plant virus

RNA replication

lipid metabolism

phospholipids

cardiolipin

Plant Biology

Plant Pathology

Plant Sciences

Função da Acil-CoA Sintetase 6 no metabolismo de músculo esquelético de ratos e humanos / Function of acyl-CoA synthetase 6 in human and rats skeletal muscle metabolism

Teodoro, Bruno Gonzaga

19 May 2016

Cinco membros da família das Acil-CoA sintetases de cadeia longa (ACSL) são responsáveis por ativar ácidos graxos, produzindo acil-CoA, e distribuí-los entre diversas vias metabólicas no interior da célula, tais como a síntese de triacilglicerol (TAG) e ?- oxidação mitocondrial. Apesar das disfunções nas ACSLs contribuirem para muitas doenças metabólicasa função de algumas isoformas de ACSL em tecidos específicos permanece ainda sem descrição na literatura. Aqui mostramos pela primeira vez a presença de mRNA da ACSL6 no músculo esquelético de seres humanos. Além disso, indivíduos obesos apresentaram menores níveis de mRNA de ACSL6 quando comparados à indivíduos magros. Após refeição hiperlipídica aguda (high fat meal, HFM, 90% de gordura) a expressão ACSL6 aumentou 2,5 vezes em relação aos níveis de jejum. Nós também verificamos as condições metabólicas que controlam a expressão ACSL6 em ratos: o jejum de 48h modulou negativamente a expressão gênica de ACSL6 e de outros genes de síntese de lipídeos tais como SREBP-1c e DGAT1, enquanto que a ingestão aguda de HFM (80% de gordura saturada , 10 mL/kg) teve o efeito oposto; Após o treinamento aeróbio (6 semanas, 5 dias /semana, uma vez por dia, 60 min a 70% da capacidade aeróbica máxima) o mRNA da ACSL6 foi reduzido em 35%. Em células primárias de músculo esquelético de ratos, a transfecção com siRNA de ACSL6 diminuiu a expressão de ACSL6, DGAT1 e SREBP-1c e o acúmulo de TAGs e gotas lipídicas. O silenciamento gênico da ACSL6 também aumentou o conteúdo dos ácidos graxos C16:0 e C18:0, AMPK-fosforilada, capacidade respiratória mitocondrial, a oxidação de palmitato e mRNA de PGC-1?, UCP2 e UCP3, mas diminuiu a produção de espécies 11 reativas de oxigênio. Em células primárias de músculo esquelético de seres humanos, a superexpressão da ACSL6 não alterou o conteúdo de TAG e da proteína DGAT1, mas aumentou as espécies lipídicas esfingomielina e fosfatidilcolinas, e reduziu a oxidação de 1-14C-palmitato e a expressão do PGC1?. Em conclusão, ACSL6 está envolvida na síntese e distribuição de acil-CoA para a síntese de lipídeos. A inibição gênica da ACSL6 melhora a capacidade de respiração mitocondrial e oxidação lipídica, através da ativação da via AMPK/PGC1?. / Five members of long-chain acyl-CoA synthetase (ACSL) family activate fatty acids providing acyl-CoA for several metabolic pathways within the cell, such as synthesis of triacylglycerol (TAG) and mitochondrial ?-oxidation, and their dysfunctions contribute to many metabolic diseases. Despite this, the existence and function of some ACSL isoforms in specific tissues remains unclear. Here we show for the first time the presence of ACSL6 mRNA and protein in skeletal muscle (SM) of humans. Obese subjects had lower levels of ACSL6 mRNA when compared to leans, and acute high fat meal (HFM, 90% fat) increased ACSL6 expression 2.5 times over fasted levels in both. We also verify the metabolic conditions that control ACSL6 expression in rats: fasting (48h) negatively modulated the ACSL6 mRNA and the expression of other genes of lipid synthesis SREBP-1c and DGAT1 in rat SM, while acute ingestion of HFM (80% saturated fat, 10 mL/Kg) had the opposite effect; After aerobic training (6 weeks, 5 days/week, once a day, 60 min at 70% of maximal aerobic capacity) ACSL6 mRNA was reduced 35%. In primary skeletal muscle cells (PSMC) of rats, ACSL6-specific siRNA oligo transfection (20 nM) decreased ACSL6, DGAT1 and SREBP-1c mRNA and the accumulation of TAGs and lipid droplets (LD). The knockdown also increased the content of C16:0 and C18:0 fatty acids, AMPK-Phosphorylated, mitochondrial content and respiratory rates, palmitate oxidation and PGC-1?, UCP2 and UCP3 mRNA, but decreased reactive oxygen species production. In PSMC of humans, ACSL6 overexpression did not change the contents of TAG or DGAT1 mRNA, but increased sphingomyelin and phosphatidylcholines and reduced 14C-palmitate oxidation and PGC1? mRNA expression. In conclusion, ACSL6 drives acyl-CoA toward lipid synthesis and its 13 downregulation improves mitochondrial capacity of respiration, lipid oxidation and biogenesis, which involves the activation of AMPK/PGC1-? pathway.

Acil-CoA Sintetase

acyl-CoA synthetase

Lipid Metabolism

Metabolismo Lipídico

Mitocôndria

Músculo esquelético

skeletal muscle mitochondria

Estudos dos produtos da oxidação não enzimática do ácido docosahexaenoico como possíveis biomarcadores para doenças neurodegenerativas / Study of Docosahexaenoic acid non-enzymatic oxidation products as biomarkers for neurodegenerative diseases

Derogis, Priscilla Bento Matos Cruz

05 September 2014

Os n-3 e n-6 são duas famílias de ácidos graxos poli-insaturados. Os ácidos graxos de cadeia longa como o ácido araquidônico (AA) e docosahexaenoico (DHA) apresentam importantes funções no desenvolvimento e funcionamento do cérebro. Os produtos de oxidação dos ácidos graxos poli-insaturados estão presentes ou aumentados ao longo do desenvolvimento de doenças neurodegenerativas. A caracterização de tais produtos é crítica para o estudo que busca entender o seu papel fisiopatológico no desenvolvimento de tais doenças. No presente trabalho, buscou-se o desenvolvimento de uma ferramenta analítica sensível e específica para a detecção e quantificação dos hidroperóxidos e hidróxidos do AA (HpETE e HETE), do seu precursor, o ácido linoleico (HpODE e HODE) e do DHA (HpDoHE e HDoHE). Estes hidroperóxidos foram sintetizados por fotooxidação e os hidróxidos correspondentes foram obtidos através da redução com o NaBH4. Os isômeros isolados foram caracterizados por LC-MS/MS. Os íons produto específicos de cada isômero foram escolhidos para a construção do método de monitoramento de reação selecionada (selected reaction monitoring - SRM) para a realização da análise quantitativa dos analitos de interesse. Cabe salientar que os dados obtidos poderão ser utilizados em bibliotecas de análise lipidômica e oxi-lipidômica pois serão essenciais para a identificação e quantificação dos analítos de interesse do presente estudo em diversas doenças. Utilizando o método padronizado, buscamos investigar o papel dos hidroperóxidos e hidróxidos do DHA, LA e AA em um modelo animal para a esclerose lateral amiotrófica (ELA), uma doença neurodegenerativa que acomete neurônios motores. Foi observado um aumento nos níveis de 13-HpODE, 9-HpODE e 12-HETE no córtex motor dos animais avaliados. Adicionalmente, foram observadas alterações nas taxas lipólica e lipogênica no tecido adiposo para os animais ELA em relação aos respectivos controles. Em conjunto, os dados apresentados no presente trabalho corroboram com os trabalhos da literatura que associam alteração dos níveis dos produtos de oxidação dos ácidos graxos poli-insaturados em doenças neurodegenerativas e o metabolismo energético alterado em ELA. Futuramente é necessária uma investigação mais ampla dos níveis dos hidroperóxidos e hidróxidos lipídicos em diferentes tecidos e do metabolismo lipídico, e os conhecimentos gerados poderão ser uma importante fonte de novas opções terapêuticas para os pacientes portadores de ELA. / The n-3 and n-6 are two olyunsaturated fatty acids families. The long chain fatty acids such as arachidonic (AA) and docosahexaenoic acid (DHA) have important roles in the development and function of the brain. Polyunsaturated fatty acids (PUFAs) oxidation products are present or increased during the progression of neurodegenerative diseases. The characterization of DHA oxidation products is critical to understand their roles in the development of such diseases. In the present study, we sought to develop a sensitive and specific analytical tool for the detection and quantification of AA hydroperoxides and hydroxides (HPETE and HETE), its precursor linoleic acid (HPODE and HODE) and DHA (HpDoHE and HDoHE). These hydroperoxides were synthesized by photooxidation and the corresponding hydroxides were obtained by reduction with NaBH4. The isolated isomers were characterized by LC-MS/MS, and unique and specific fragment ions were chosen to construct a selected reaction monitoring (SRM) method for the targeted quantitative analysis. It should be emphasized that the data obtained - in the form of lipidomics and oxy-lipidomics libraries - may be used to assist in several diseases. Using the standardized method, we investigated the role of hydroperoxides and hydroxides of DHA, LA and AA in an animal model of amyotrophic lateral sclerosis (ALS), a neurodegenerative disease that affects motor neurons. Increased levels of 13-HPODE, 9-HPODE and 12-HETE were observed in the animals motor cortex. Additionally, results show changes in lipogenic and lipolytic rates in adipose tissue for ALS animals when compared to their respective controls. Altogether, the data presented herein corroborate with the literature by linking altered levels of PUFAs oxidation products in neurodegenerative diseases with altered energetic metabolism in ALS. In the future, a more extensive investigation of the hydroperoxide and hydroxide level in different tissues as well as the lipid metabolism must be done, which could lead to new therapeutic options for ALS patients

Ácido docosahexaenoico

Docosahexaenoic acid

Espectrometria de massas

Lipid metabolism

Mass spectrometry

Metabolismo lipídico

Oxidation products

Produtos de oxidação

Étude de l’infection de la microsporidie Tubulinosema ratisbonensis sur son hôte Drosophila melanogaster : importance du métabolisme lipidique de l’hôte dans la prolifération parasitaire / Study of Drosophila melanogaster infection by the microsporidia Tubulinosema ratisbonensis : importance of host lipid metabolism for the parasitic proliferation

Franchet, Adrien

17 December 2015

Nous étudions les interactions hôte/pathogène entre la drosophile et un parasite intracellulaire, la microsporidie Tubulinosema ratisbonensis.Les microsporidies dérivent du groupe des champignons possédant un génome réduit et pas de mitochondrie. Ces parasites dépendent fortement du métabolisme de leur hôte pour proliférer. Les interactions entre les microsporidies et leurs hôtes reste peu étudiées au niveau métabolique.In vivo, les spores ciblent beaucoup de tissues, en particulier le corps gras qui perd ces gouttelettes lipidiques. Les réserves métaboliques sont épuisées au cours de l’infection et les mouches présentent les caractéristiques de famine. La supplémentation en acide gras dans la nourriture des mouches infectées augmente la prolifération du parasite. Cet effet est bloqué lorsque l’on perturbe l’assimilation ainsi que le transport des lipides provenant de l’intestin. En conséquence, les mouches résistent mieux à l’infection lorsque la synthèse des lipides est bloquée. / We study the host/pathogen interactions between Drosophila and a natural intracellular parasite : the microsporidium Tubulinosema ratisbonensis. Microsporidia are highly derived group of fungi with a compact genome and no mitochondria. These obligate parasites thus rely intensively on host metabolism for growth and proliferation. The interactions between microsporidia and their hosts remain poorly understood at the metabolic level.In vivo, spores target many tissues especially the fat body that loses its lipid droplets. Metabolic reserves become depleted during the course of the infection and flies display the hallmarks of severe starvation. Fatty acids supplementation of the infected flies diet increases parasite proliferation and host susceptibility to the parasite. This effect is blocked when perturbing lipid assimilation and transport originating from the gut. Accordingly, flies resist better infection when lipid synthesis is blocked, as the parasite proliferation is hampered.

Drosophila melanogaster

Microsporidie

Métabolisme lipidique

Drosophila melanogaster

Microsporidia

Lipid metabolism

579.3

572.4

Efeito da ingestão do óleo de amaranto no metabolismo lipídico de hamsters / Effect of amaranth oil on lipid metabolism of hamsters

Castro, Luíla Ivini Andrade de

09 May 2011

Introdução. O amaranto é um pseudocereal de alto valor nutritivo, além de apresentar propriedade de redução do colesterol plasmático. O conteúdo lipídico de seus grãos é superior ao dos cereais comuns, com elevado teor de ácidos graxos insaturados, além de apresentar quantidade significante de esqualeno, um dos possíveis compostos bioativos responsáveis pela redução do colesterol. Objetivo. Verificar o efeito do óleo de amaranto e do esqualeno no metabolismo lipídico de hamsters alimentados com gordura saturada e colesterol. Metodologia. O óleo de amaranto foi extraído por solvente orgânico (n-hexano) e analisado nos seus conteúdos de esqualeno. O potencial efeito hipocolesterolemizante deste óleo foi avaliado mediante um ensaio biológico, em que foram utilizados 40 hamsters recémdesmamados. Os animais foram divididos em 4 grupos de 10, diferenciados pelas dietas: controle [dieta normal com 20% de óleo de milho] (C), hipercolesterolêmica [dieta com 12% de gordura de côco, 8% de óleo de milho e 0,1% de colesterol] (H), óleo de amaranto [idêntica à (H) com óleo de amaranto substituindo o de milho] (A) e esqualeno [idêntica à (H) + esqualeno na proporção encontrada no óleo de amaranto] (E), formuladas segundo as recomendações da NRC (1995) e AIN-93. Após 28 dias de experimento, os animais tiveram o sangue coletado por punção cardíaca, sob anestesia, sendo determinados o colesterol total, triglicérides, HDL-c e colesterol não-HDL plasmáticos. Após sacrifício, os fígados dos animais foram coletados para a realização da análise histológica e do teor de colesterol. Também foram determinados os teores de colesterol e ácidos biliares das fezes dos animais. Resultados. Não houve diferença estatisticamente significante no perfil lipídico e excreção fecal de colesterol dos animais dos grupos hipercolesterolêmico, óleo de amaranto e esqualeno. A excreção fecal de ácidos biliares foi maior nos animais dos grupos óleo de amaranto e esqualeno em comparação com os grupos controle e hipercolesterolêmico. O teor de colesterol hepático dos animais do grupo esqualeno foi maior em relação aos outros grupos, embora tenha se diferenciado estatisticamente apenas do grupo controle. Em relação à análise histológica hepática, os maiores graus de esteatose e inflamação parenquimatosa foram os dos grupos óleo de amaranto e esqualeno. Conclusões. O óleo de amaranto e o seu componente esqualeno não apresentaram efeito hipocolesterolemizante e promoveram um aumento da excreção de ácidos biliares em hamsters alimentados com dieta contendo elevadas quantidades de gordura saturada e colesterol. / Introduction: Amaranth is a pseudo cereal of superior nutritional value, besides its property of reducing serum cholesterol. The lipid content of the grains is higher than common cereals, with high content of unsaturated fatty acids. Amaranth also presents significant amounts of squalene, a possible bioactive compound responsible for lowering cholesterol. Objective: To investigate the effect of amaranth oil and squalene on lipid metabolism in hamsters fed with saturated fat and cholesterol. Methodology: The amaranth oil was extracted by organic solvent (n-hexane) and its content of squalene was determined. The potential hypocholesterolemic effect of this oil was evaluated by a bioassay, which employed 40 weanling hamsters. The animals were divided into four groups of 10, differentiated by the diets: control [normal diet with 20% corn oil] (C), hypercholesterolemic [diet with 12% fat coconut, 8% corn oil, and 0.1% cholesterol] (H) amaranth oil [identical to (H) with amaranth oil replacing corn oil] (A) and squalene [identical to (H) + squalene in the proportion found in the amaranth oil] (E). They were all formulated according to the recommendations of NRC (1995) and AIN-93. After 28 days, the animals had blood collected by cardiac puncture, under anesthesia, being measured total cholesterol, triglycerides, HDL-C and plasma non-HDL cholesterol. After sacrifice, the livers of animals were collected for histological analysis and determination of cholesterol content. We also determined the levels of cholesterol and bile acids in the feces of animals. Results: There was no statistically significant difference in lipid profile and fecal excretion of cholesterol from animals in the hypercholesterolemic, amaranth oil and squalene groups. Fecal excretion of bile acids was higher in animals in groups of amaranth oil and squalene as compared with the control group and hypercholesterolemic group. The cholesterol content in liver of the animals from squalene group was higher compared to other groups, although this difference was not statistically significant except when compared to the control group. The highest grade of steatosis and parenchymal inflammation were found in the groups of amaranth oil and squalene. Conclusions: The amaranth oil and its component squalene had no effect hypocholesterolemic and promoted an increased excretion of bile acids in hamsters fed a diet containing high amounts of saturated fat and cholesterol.

Alimentos funcionais

Amaranth oil

Esqualeno

Functional food

Hamsters

Hamsters

Lipid metabolism

Metabolismo lipídico

Óleo de amaranto

Squalene